KR20140081009A - Holder of entry nozzle for easy non-oxidizing molding - Google Patents

Abstract

The present invention relates to a dipping nozzle holder including a holder body joined to the upper outer side of a dipping nozzle of a continuous casting device; and holder grippers formed on both sides of the holder body and holding the dipping nozzle. The dipping nozzle holder is characterized by including a deformation preventing groove formed on the inner surface of the dipping nozzle holder along the inner circumference to be recessed inward and multiple heat discharging holes punched on the deformation preventing groove. The present invention prevents the deformation and contraction of the dipping nozzle holder caused by radiant heat generated when preheating a tundish and the dipping nozzle by forming the deformation preventing groove, the heat discharging holes, and a supporting member on the dipping nozzle holder, thereby enabling non-oxidizing casting. Furthermore, the dipping nozzle holder prevents the heat of molten steel from being discharged to the outside when continuous casting, thereby preventing an inlet of the dipping nozzle from being clogged with inclusion.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an immersion nozzle holder,

More particularly, the present invention relates to an immersion nozzle holder which is easy to perform an anaerobic casting operation, and more particularly, to an immersion nozzle holder in which a deformation preventing groove, a heat discharging hole and a supporting member are formed in the immersion nozzle holder, To prevent the immersion nozzle holder from being deformed and shrunk to enable the non-oxidizing casting operation and to prevent the heat of molten steel from flowing out to the outside during the continuous casting operation, thereby preventing the immersion nozzle inlet from being blocked by the inclusions To an immersion nozzle holder which is easy to work.

In general, the continuous casting operation is carried out by injecting molten steel into the tundish 13 through the long nozzle 12 connected to the ladle 10 containing molten steel, as shown in FIGS. 1 and 2, When the dish 13 is filled, the inclusion contained in the dish 13 is separated.

Thereafter, when the mid plate 21 of the molten steel injection control device 16, which is familiar to the tundish 13, is opened, molten steel is injected into the mold 19 through the immersion nozzle 18.

The injected molten steel forms a solidification cell in the mold 19 and is coagulated and cooled to form a slab 20.

The long nozzle 12 connected to the ladle 10 can freely separate and engage while the immersion nozzle 18 connected to the tundish 13 is connected to the bottom of the tundish 13, And is fixedly attached to the arm 22 of the injection control device 16 so as to be separated and removed after the casting operation is completed.

Therefore, the immersion nozzle 18 functions as a conduit for guiding molten steel to be injected so as not to be in contact with oxygen.

The immersion nozzle 18 is seated in the arm 22 coupled to the cylinder 15 of the molten steel injection control device 16 so that the immersion nozzle 18 can not be independently coupled.

4, after the immersion nozzle 18 is inserted into the inner diameter of the holder 24, the holder 24 is brought up to the upper side of the injection port 18 of the immersion nozzle 18 and engaged. Thereafter, the holder handle of the holder 24 is mounted so as to be seated in the groove portion of the arm 22, whereby the immersion nozzle 18 is joined to the molten steel injection control device 16. [

When the immersion nozzle 18 is coupled to the molten steel injection control device 16 as described above, the cylinder 15 rises and the injection port of the immersion nozzle 18 is brought into tight contact with the lower nozzle 23 at a constant pressure.

The tundish 13 and the immersion nozzle 18 are preheated to a predetermined temperature to prevent temperature compensation of the molten steel and clogging of the injection port during the casting operation. As shown in FIG. 3, The heater 27 is preheated for a predetermined time and the immersion nozzle 18 closes one side of the discharge port and the burner 26 is provided on the other side to preheat the flame so as to flow into the inner diameter of the immersion nozzle 18.

The rod of the cylinder 14 of the molten steel injection control device 26 is moved so that the mid plate 21 is pulled toward the cylinder 14 so that the ball pierced through the mid plate 21 ), So that the movement of the flame becomes free.

When the tundish 13 and the immersion nozzle 18 are preheated, the holder 24, which surrounds the outer diameter of the inlet of the immersion nozzle 18, is directly affected by exposure to high-temperature radiant heat, Similarly, shrinkage and deformation due to thermal deformation will occur. 5 (a) shows a section of the holder 24 which is not deformed, and (b) and (c) show a section of the holder 24 deformed by radiant heat.

6, when the holder 24 is deformed, the injection port of the immersion nozzle 18 to be tightly coupled with the lower nozzle 23 can not be perfectly attached to the immersion nozzle 18, There is a problem that the molten steel 25 is reoxidized by contaminating the molten steel 25 to be injected.

During the continuous casting operation, the holder 24 removes the temperature of the molten steel 25 injected into the immersion nozzle 18, causing fusion of the inclusions to grow, causing clogging of the injection port of the immersion nozzle 18, ), And there is a problem that the casting operation is interrupted due to clogging of the injection port of the immersion nozzle (18).

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide an immersion nozzle holder in which a deformation preventing groove, a heat discharging hole and a supporting member are formed, It is possible to prevent the holder from being deformed and shrunk to enable the non-oxidizing casting operation and to prevent the heat of the molten steel from flowing out to the outside during the continuous casting operation, thereby preventing the immersion nozzle injection port from being clogged by the inclusions. Thereby providing an immersion nozzle holder.

According to the present invention, there is provided an immersion nozzle holder including a holder main body coupled to an outside of an upper portion of an immersion nozzle of a continuous casting apparatus, and a holder handle formed on both sides of the holder main body to hold an immersion nozzle, And a plurality of heat discharging holes formed in the deformation preventing grooves.

In addition, the deformation preventing groove may not be formed near the region where the holder handle is formed.

Further, it may further include a support member provided inside the deformation preventing groove and supporting upper and lower portions and side inner surfaces of the deformation preventing groove.

The apparatus may further include a plurality of communication holes formed in the support member to communicate with the heat exhaust holes.

In addition, the support member may be provided in a plurality of rhombic shapes so as to be connected to each other.

In addition, the support member may be formed so that its cross-sectional area gradually decreases from the inside to the outside of the holder body.

Thus, deformation preventing grooves, heat exhaust holes and supporting members are formed in the immersion nozzle holder to prevent the immersion nozzle holder from being deformed and shrunk by radiant heat generated during the tundish and the immersion nozzle preheating operation. Thereby preventing the heat of the molten steel from flowing out to the outside during the continuous casting operation, thereby preventing the immersion nozzle inlet from being blocked by the inclusions.

Figures 1-6 are diagrams of the prior art.
FIG. 7 is a perspective view and a cross-sectional view of an immersion nozzle holder that facilitates an anaerobic casting operation according to the present invention.
8 is a cross-sectional perspective view and a cross-sectional view of an immersion nozzle holder that facilitates an anaerobic casting operation according to the present invention.
FIGS. 9 and 10 are views showing that an immersion nozzle holder, which facilitates an anaerobic casting operation, according to the present invention is installed in an immersion nozzle.
FIG. 11 is a view showing that an immersion nozzle holder, which is easy to perform an anaerobic casting operation according to the present invention, is installed in a continuous casting apparatus.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.

Prior to describing the present invention, the same components as those of the prior art will be referred to by reference to the prior art.

As shown in FIG. 7, the immersion nozzle holder facilitates the anaerobic casting operation according to the present invention includes a holder body 100 coupled to the outside of the upper portion of the immersion nozzle 18, A deformation preventing groove 120 formed to be recessed inward along the inner circumference of the inner side surface of the holder body 100 and a plurality of heat discharging holes 120 formed in the deformation preventing groove 120, 130).

First, the holder body 100 is a ring-shaped member having a hole corresponding to the outer diameter of the immersion nozzle 18 at its center, and the lower side is formed to be narrowed toward the center side. In other words, the holder main body 100 is formed in the same shape as the shape of the upper end of the injection port of the immersion nozzle 18 while being kept in a constant inner diameter and becoming narrower. The holder body 100 formed as described above is fitted to the upper end side of the immersion nozzle 18 and is engaged.

On both sides of the holder main body 100, a rod-shaped holder handle 110 having a predetermined length is provided. The holder handle 110 is seated and fixed to the arm 22 of the molten steel injection control device 16.

The deformation preventing groove 120 is a rectangular groove formed so as to be recessed along the inner circumference of the holder body 100. The deformation preventing groove 120 is formed in the inner surface of the holder body 100 except for the portion where the holder handle 110 is formed. Respectively. The deformation preventing groove 120 is formed in a shape of a rectangular band on the inner surface of the holder main body 100 except for the portion where the holder handle 110 is formed by bisecting the inner side surface of the holder main body 100 with respect to the holder handle 110. [ As shown in FIG. The reason why the deformation preventing groove 120 is not formed in the portion where the holder handle 110 is formed is to reinforce the strength of the portion where the holder handle 110 is formed. The holder main body 100 can not bear the weight of the immersion nozzle 18 and the portion where the holder main body 100 and the holder handle 110 are connected can be damaged when the prevention groove 120 is formed.

9, the deformation preventing groove 120 is for forming a predetermined space between the outer diameter of the immersion nozzle 18 and the holder main body 100, and the deformation preventing groove 120 , All of the radiant heat generated when the immersion nozzle 18 is preheated is prevented from being conducted to the holder main body 100.

On the other hand, the heat discharging hole 130 is a hole formed in the deformation preventing groove 120 to the outside of the holder body 100, and the heat discharging hole 130 is perforated in each of the deformation preventing grooves 120 in plural. The heat discharging hole 130 is for discharging radiant heat generated when the immersion nozzle 18 is preheated to the outside of the holder main body 100, as shown in FIG.

It is possible to prevent all the radiant heat generated at the time of preheating the immersion nozzle 18 from being conducted to the holder body 100 by the deformation preventing groove 120 and to prevent part of the radiant heat conducted by the heat discharging hole 130 from being transferred to the outside The holder main body 100 is prevented from being deformed and shrunk by radiant heat.

8 and 10, the immersion nozzle holder according to the present invention is provided in the interior of the deformation preventing groove 120 so that the upper and lower portions of the deformation preventing groove 120, And a support member 140 for supporting the inner surface.

The supporting member 140 is formed such that a plurality of rhombic shapes are mutually connected, and upper and lower vertexes of the rhombic shape are provided so as to abut against the upper and lower portions of the deformation preventing groove 120, Preventing grooves 120 and the entirety of the deformation preventing grooves 120 is provided. Here, the support member 140 is formed with a plurality of communication holes which are communicated with the heat exhaust holes 130 separately. At this time, the support member 140 is formed such that its cross-sectional area gradually decreases from the inside to the outside of the holder main body 100.

The support member 140 prevents the entire radiant heat from being conducted by the deformation preventing grooves 120 and the heat exhaust holes 130 formed in the holder body 100, Is prevented from being deformed and contracted by supporting the entire inner surface of the deformation preventing groove 120 when the deformation preventing groove 120 is deformed and reduced.

11 is a view showing that the immersion nozzle holder is easily installed in the continuous casting apparatus according to the present invention. In the case where the tundish 13 and the immersion nozzle 18 are heated by radiant heat generated during preheating, The lower end of the lowering nozzle 23 and the upper injection port of the immersion nozzle 18 are tightly engaged with each other to prevent the oxygen from contacting the molten steel 25, do.

In addition, since the immersion nozzle holder according to the present invention easily maintains the area of the holder body 100 contacting the outer diameter of the immersion nozzle 18 by the deformation preventing groove 23 to a minimum, Since the heat of the molten steel 25 is minimally lost by the holder main body 100 when the molten steel 25 is discharged through the immersion nozzle 18, the inclusions are fused and grown at the top of the injection port of the immersion nozzle 18 Thereby preventing the injection port of the immersion nozzle 18 from being clogged.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. It will be understood that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims.

10: Ladle 12: Long nozzle
13: Tundish 14, 15: Cylinder
16: molten steel injection control device 18: immersion nozzle
19: mold 21: mid plate
22: arm 23: loose nozzle
24: holder 25: molten steel
26: Burner 27: Preheater
100: holder body 110: holder handle
120: deformation preventing groove 130: heat discharging hole
140: support member

Claims (6)

1. An immersion nozzle holder comprising: a holder body coupled to an upper portion of an upper portion of an immersion nozzle of a continuous casting apparatus; and a holder handle formed on both sides of the holder body to hold an immersion nozzle,
A deformation preventing groove formed on the inner side surface of the holder body so as to be recessed along an inner circumference thereof;
And a plurality of heat exhaust holes formed in the deformation preventing grooves. The method according to claim 1,
Wherein the deformation preventing groove is not formed near the region where the holder handle is formed. The method according to claim 1,
And a support member provided inside the deformation preventing groove and supporting upper and lower portions and side inner surfaces of the deformation preventing groove. The method of claim 3,
And a plurality of communication holes formed in the support member to communicate with the heat exhaust holes. The method of claim 3,
Wherein the support member is provided in a plurality of rhombic shapes and is connected to one another in a continuous manner. The method of claim 3,
Wherein the support member is formed such that the cross-sectional area of the support member gradually decreases from the inside to the outside of the holder main body.

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