KR101951840B1 - Apparatus for heating submerged nozzle of turndish - Google Patents

Abstract

The present invention relates to a preheating apparatus for preheating a submerged nozzle of a tundish mounted in a tundish car to easily perform preheating work with respect to the submerged nozzle anywhere and anytime in case of necessity and, more specifically, provides an apparatus for preheating a submerged nozzle of a tundish, which comprises: a housing surrounding the submerged nozzle; a burner installed in the housing to preheat the submerged nozzle by applying heat to the inside of the housing; and a swing unit installed in the tundish car, and connected to the housing for the housing to move to surround the submerged nozzle or be separated from the submerged nozzle.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a tundish immersion nozzle preheating apparatus,

A preheating device for preheating an immersion nozzle mounted on a tundish is disclosed.

In general, the continuous casting facility is a facility that continuously receives slabs of a certain size by receiving the molten steel conveyed to the rollers on a tundish and supplying them to a mold.

The continuous casting equipment includes a raft turret for supporting rails and rolls containing refined molten steel in a steelmaking process, a tundish for temporarily storing molten steel after being supplied with molten steel from the rails and distributing the molten steel to each strand, Lt; / RTI >

The tundish receives the molten steel from the rails to continuously supply slabs to the mold. In the lower part of the tundish, an immersion nozzle for injecting molten steel into the mold is provided. Accordingly, the molten steel supplied from the reed to the tundish is injected into the mold through the immersion nozzle provided at the bottom of the tundish to be made into a cast steel.

The immersion nozzle provided in the tundish is used after preheating to remove residual water generated during refractory construction and to minimize the loss of molten steel and heat loss of molten steel.

In the prior art, the preheating operation of the immersion nozzle of the tundish was accomplished by moving the tundish car to the designated preheat location. The tundish car placed with the tundish was moved to the designated position, and the immersion nozzle was preheated using an oven.

Therefore, it is possible to preheat only at the designated preheating position, and it is impossible to preheat the immersion nozzle at a position other than the designated position. Accordingly, in the conventional case, when the tundish needs to wait for a while due to facility trouble or other causes, there is a problem that the preheating can not be performed even though the temperature of the immersion nozzle drops.

In the case of a tundish, the temperature of the molten steel to be injected is compensated to some extent even if the internal temperature drops slightly. However, in the immersion nozzle for inducing molten steel injection into the mold, cracks are generated even in a small temperature variation. In addition, at the lower end of the injection port of the immersion nozzle in which the temperature deviation is severely generated, there is a problem that the nozzle is clogged due to solidification of molten steel.

There is provided a tundish immersion nozzle preheating apparatus capable of easily performing a preheating operation for an immersion nozzle at any position and at any time.

A tundish immersion nozzle preheating apparatus is provided which can further increase the preheating efficiency of the immersion nozzle.

This embodiment is a preheating device for preheating an immersion nozzle of a tundish mounted on a tundish, comprising: a housing surrounding the immersion nozzle; a burner installed in the housing to preheat the immersion nozzle by applying heat to the interior of the housing; And a swing unit installed in the tundish car and connected to the housing to move the housing to wrap the immersion nozzle or separate the immersion nozzle from the immersion nozzle.

The housing may have a larger diameter toward the lower end.

The burner may be installed at a position corresponding to the molten metal discharge port of the immersion nozzle while the housing is enclosing the immersion nozzle.

The housing may include an iron core forming an outer shape, and a refractory provided on an inner surface of the iron core.

And a retention plate which is provided along the inner circumferential surface of the housing and whose tip extends toward the immersion nozzle to form a gap with the immersion nozzle.

The housing may be structured such that it is separated into at least two or more along the circumferential direction of the immersion nozzle, and each of the divided parts closely contacts with the immersion nozzle.

The housing may include a first semicircular second semicylinder that is divided into two portions along the circumferential direction of the immersion nozzle and closely contacted with each other to surround the immersion nozzle.

The housing may further include a joint portion continuously formed along the first semi-cylindrical tip and covering the joint surface of the second semicircular passage.

The housing may further include an engaging member provided at the first semi-cylindrical tip to engage a refractory disposed inside the first semicircular first semi-cylindrical body.

The swing unit may be installed in a separate part of the housing to move the respective parts.

Wherein the swing portion includes a bracket provided at a lower portion of the tundish car, a rotary arm rotatably coupled to the bracket around a hinge axis, a rotary arm provided at one end thereof with a divided portion of the housing, And a drive cylinder that rotates the rotary arm about the hinge axis to move a divided portion of the housing.

The first semicircular second semicylindrical tube is provided on each of the swing arms of each swinging part so that the first semicircular second semicylindrical tube is gathered by the rotation of the rotary arm, The nozzle may be surrounded or separated from the immersion nozzle.

As described above, according to this embodiment, it is possible to preheat the immersion nozzle of the tundish at any time in the process of moving the tundish carrot tundish.

Thus, even during the tundish atmosphere, the temperature of the immersion nozzle can be prevented from being lowered, and the temperature can be maintained at a constant temperature, thereby minimizing damage to the immersion nozzle or clogging of the molten metal during the molten metal injection process.

The driving and preheating of the apparatus for preheating the immersion nozzle can be performed more easily, so that the immersion nozzle preheating operation can be performed more easily.

1 is a schematic view showing a tundish immersion nozzle preheating apparatus provided in a tundish car according to an embodiment of the present invention.
2 is an exploded perspective view showing a configuration of a tundish immersion nozzle preheating apparatus according to the present embodiment.
FIGS. 3 and 4 are schematic views showing an operating state of the swing portion of the tundish immersion nozzle preheating apparatus according to the present embodiment.
5 to 7 are schematic views showing the housing of the tundish immersion nozzle preheating apparatus according to the present embodiment.
FIGS. 8 and 9 are schematic views showing the immersion nozzle preheating structure of the tundish immersion nozzle preheating apparatus according to the present embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. 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 or scope of the invention. Wherever possible, the same or similar parts are denoted using the same reference numerals in the drawings.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the invention. The singular forms as used herein include plural forms as long as the phrases do not expressly express the opposite meaning thereto. Means that a particular feature, region, integer, step, operation, element and / or component is specified, and that other specific features, regions, integers, steps, operations, elements, components, and / And the like.

All terms including technical and scientific terms used herein have the same meaning as commonly understood by those of ordinary skill in the art to which the present invention belongs. Predefined terms are further interpreted as having a meaning consistent with the relevant technical literature and the present disclosure, and are not to be construed as ideal or very formal meanings unless defined otherwise.

FIG. 1 shows an immersion nozzle preheating apparatus installed in a lower part of a tundish according to the present embodiment, and FIG. 2 is an exploded view of the immersion nozzle preheating apparatus according to the present embodiment.

As shown in FIG. 1, the tundish 100 is seated on the tundish car 200 and moved. In the tundish 100, an immersion nozzle 110 is connected to the lower portion. The immersion nozzle 110 is installed downward in the vertical direction from the lower portion of the tundish 100. The immersion nozzle 110 is a tubular structure having a long elongated shape, and a molten steel discharge port 112 through which molten steel is discharged is formed on the lower side surface.

The preheating device of this embodiment for preheating the immersion nozzle 110 is installed under the tundish car 200 and moves together with the tundish car. If necessary, the immersion nozzle 110 of the tundish which is seated in the tundish car Wrap it up and preheat. Accordingly, if the preheating of the immersion nozzle 110 is required at the current tundish standby position without moving the tundish car 200 to the predetermined position, the preheating operation can be performed immediately.

To this end, the preheating apparatus of this embodiment includes a housing 10 surrounding the immersion nozzle 110, a burner 16 installed in the housing 10 to preheat the immersion nozzle 110 by applying heat to the interior of the housing 10, And a swing unit 50 installed in the tundish car 200 and connected to the housing 10 to move the housing 10 to enclose the immersion nozzle 110 or separate the immersion nozzle 110 from the immersion nozzle 110 .

The housing 10 provided under the tundish car 200 may be moved to the immersion nozzle 110 through driving of the swing unit 50 if necessary and the immersion nozzle 110 may be wrapped around the immersion nozzle 110 to perform preheating.

The housing 10 may take the form of a container having an internal space. In the present embodiment, it may have a cylindrical cross-sectional structure such as the immersion nozzle 110. In the housing 10, a hole is formed to allow the immersion nozzle 110 to pass therethrough, and the immersion nozzle 110 is wrapped with the container structure in which the lower end and the side are closed.

The housing 10 may have a structure in which the housing 10 is divided into a plurality of portions so that the housing 10 can be easily wrapped. That is, the housing 10 may be divided into at least two portions along the circumferential direction of the immersion nozzle 110, and each of the divided portions may be in close contact with each other to surround the immersion nozzle 110. For example, the housing 10 may be divided into a number of different configurations, such as a 180 degree angle along the circumference at the axis center, a 3 minute 120 degree angle, or a 4 minute 90 degree angle. Accordingly, when the housing 10 is coupled to the immersion nozzle 110 so as to enclose the immersion nozzle 110, it is possible to more easily engage the immersion nozzle 110. When the housing 10 is formed as a single body, the housing 10 is moved upwards from the bottom of the immersion nozzle 110 to install the immersion nozzle 110 through the hole in the upper end of the housing 10 do. However, in the case of this embodiment, the plurality of divided housings 10 are moved in the lateral direction of the immersion nozzle 110 to cover the immersion nozzle 110. In such a structure, the housing 10 is moved toward the immersion nozzle 110, so that the immersion nozzle 110 can be wrapped around the housing 10 without moving the height of the tundish car 200 in the vertical direction . Therefore, in the present embodiment, the preheating operation for the immersion nozzle 110 can be performed easily without adjusting the rising and falling heights of the tundish car 200.

Hereinafter, the present embodiment will be described by taking as an example a structure divided into two by an angle of 180 degrees along the circumferential direction of the housing 10. As mentioned, the housing 10 is not limited to a structure divided into two parts and can be separated into various numbers.

2, the housing 10 of the present embodiment may include a first semi-cylindrical 12 and a second semi-cylindrical 14 which are separated into two and closely contact with each other to enclose the immersion nozzle 110 . A half of the housing 10 located on the left side in FIG. 2 is referred to as a first half cylinder 12 and a half of the housing 10 located on the right side is referred to as a second half cylinder 14 for convenience of explanation. The housing 10 refers to both the first half cylinder 12 and the second half cylinder 14 or the first half cylinder 12 and the second half cylinder 14 are in close contact with each other to form a complete cylinder State can be referred to. In this embodiment, the first semi-cylindrical portion 12 and the second semi-cylindrical portion 14 can be arranged in accordance with the formation direction of the molten metal discharge port 112 at the lower end of the immersion nozzle 110.

Two swing portions 50 for moving the housing 10 are also provided and are connected to the first half cylinder 12 and the second half cylinder 14, respectively. Two swing parts 50 are disposed opposite to each other with respect to the immersion nozzle 110 so that a first semi-cylindrical part 12 and a second semi-cylindrical part 14 are provided in each swing part 50. As the swinging part 50 is driven, the first semi-cylindrical part 12 and the second semi-cylindrical part 14 are gathered to form a single housing 10 to enclose the immersion nozzle 110, (110).

As shown in FIG. 2, two swing portions 50 are disposed facing each other and connected to the first semi-cylindrical portion 12 and the second semi-cylindrical portion 14, respectively. Since the respective swing portions 50 are formed in the same configuration as each other, only the directions are opposite to each other, the same reference numerals are used and only the swing portion 50 connected to the first half cylinder 12 will be described. The structure of the portion 50 is equivalent to this.

The swing portion 50 is rotatably coupled to the bracket 52 and the hinge shaft 54 at a lower portion of the tundish car 200, A rotating arm 56 provided on the bracket 52 and connected to the other end of the rotary arm 56 to rotate the rotary arm 56 about the hinge shaft 54 to rotate the housing 10, (Not shown).

The bracket 52 is coupled to the lower portion of the tundish car 200 to axially support the drive cylinder 58 and the rotary arm 56. The bracket 52 can be variously deformed in structure to support the driving cylinder 58 and the rotary arm 56. [

The rotary arm 56 is rotatably mounted on the bracket 52 via a hinge shaft 54 at one side between the both ends. The rotary arm 56 rotates about the hinge axis 54 so that both ends of the rotary arm 56 perform a seesaw motion. One end of the rotary arm (56) is coupled to a fastening member provided on the first semi-cylindrical body (12). The other end of the rotary arm (56) is axially coupled to the piston rod end of the drive cylinder (58). The rotary arm 56 may be bent at various angles so as to be coupled with the housing 10 under the tundish car 200 and rotate the housing 10 without interference. The shape of the rotary arm 56 can be variously modified.

The drive cylinder 58 is spaced apart from the hinge shaft 54 of the rotary arm 56 and is axially coupled to one side of the bracket 52. 3 and 4, when the driving cylinder 58 is stretched and driven to exert a force on the other end of the rotary arm 56, the rotary arm 56 is rotated about the hinge axis 54 . Therefore, the first semi-cylindrical cylinder 12 provided at the tip of the rotary arm 56 moves with the hinge axis 54 as a turning radius, and is coupled to the immersion nozzle 110 or moved away from the immersion nozzle 110.

The rotation angle of the rotary arm 56, which rotates about the hinge axis 54, may be approximately 90 degrees. 3 and 4, the first semicylinder 12 provided at the tip of the rotary arm 56 is erected in accordance with the rotation angle of the rotary arm 56 and is coupled to the immersion nozzle 110, 0.0 > 110 < / RTI >

That is, when the drive cylinder 58 is extended, the first semicylinder 12 mounted on the rotary arm 56 moves outward from the immersion nozzle 110 along the rotation radius of the rotary arm 56. When the rotary arm 56 is completely rotated, the first semi-cylindrical body 12 is laid down in the x-axis direction and completely separated from the immersion nozzle 110.

The first semi-cylindrical body 12 provided on the rotary arm 56 is moved toward the immersion nozzle 110 along the rotation radius of the rotary arm 56 while the drive cylinder 58 is contracted. When the rotary arm 56 is completely rotated, the first semi-cylindrical body 12 is also completely moved toward the immersion nozzle 110, and is raised in the y-axis direction to cover the immersion nozzle 110.

The second semicylinder 14 disposed on the opposite side of the first semicylinder 12 is also completely moved to the immersion nozzle 110 and stands in the y axis direction to cover the other portion of the immersion nozzle 110. Accordingly, the first semi-cylindrical portion 12 and the second semi-cylindrical portion 14 are gathered together while the rotary arm 56 is rotated according to the driving of each swinging portion 50. [ Accordingly, as shown in FIG. 8, the first semi-cylindrical body 12 and the second semi-cylindrical body 14 are gathered and closely contacted to form a single housing 10 to cover the immersion nozzle 110.

The structure of the housing will be described with reference to Figs. 5 to 7. Fig.

The first semi-cylindrical portion 12 on the left side in FIG. 5 is formed with a joining portion 18 that surrounds the tip of the second semi-cylindrical portion 14 at the tip end thereof in contact with the second semi-cylindrical portion 14. A burner 16 is installed below the second semicylinder 14. The first semi-cylindrical portion 12 and the second semi-cylindrical portion 14 are separated from each other by cutting a cylinder, and are in contact with each other to form a single cylindrical or housing 10.

The first semi-cylindrical portion 12 and the second semi-cylindrical portion 14 constituting the housing 10 may have a structure in which the diameter increases toward the lower end. For example, the housing 10 may have a frusto-conical cross-section structure. Accordingly, the inner space of the housing 10 is relatively wider as the lower space is lower than the upper space. Therefore, the residence time of the flame applied to the lower portion of the housing 10 is increased, and the preheating effect can be enhanced.

Figure 6 shows the first half cylinder (12). As shown in FIG. 6, the first semi-cylindrical body 12 may include a metal foil 20 having an outer shape and a refractory 22 provided on the inner surface of the metal foil 20 in a half-cut shape. The upper end of the scoop 20 is cut into a semicircular shape so as to be in close contact with the side surface of the immersion nozzle 110. A fastening member 24 for fastening the swing arm 50 to the distal end of the rotary arm 56 is formed on the outer surface of the scrim 20. The fastening member 24 may have a structure in which a fitting groove is formed so that the tip of the rotary arm 56 is fitted and can be easily coupled with a bolt or the like. The structure of the fastening member 24 and the fastening structure with the distal end of the rotary arm 56 can be variously modified.

The refractory 22 is formed in a shape corresponding to the refractory 20 and is installed inside the refractory 20. The refractory 22 may be formed by constructing the refractory 22 in a shape corresponding to the refractory 20. The refractory 22 has the same shape as the refractory 20 and is formed into a size that can enter the refractory 20 and is inserted into the refractory 20 through the open front of the refractory 20. The refractory 22 is formed in the same shape as the iron foil 20 and can be easily separated from the iron foil 20 while being mounted inside the iron foil 20. Therefore, when replacement is required after use or breakage, the refractory 22 can be separated from the refractory 20 and a new refractory 22 can be inserted into the refractory 20. In addition to this structure, the refractory material can be formed by adhering a monolithic refractory material on the inner surface of the refractory 20. The refractory 22 may be any material that can withstand the high temperature inside the foil 20 and minimize heat conduction to the foil 20.

A joining portion 18 is formed at the front end of the first semi-cylindrical portion 12 to cover the joining face between the front end of the first semi-cylindrical portion 12 and the front end of the second semi-cylindrical portion 14 in contact therewith. The joining portion 18 projects outward from the tip of the first semi-cylindrical portion 12 and is bent so as to cover the joining surfaces of the first semi-cylindrical portion 12 and the second semi-cylindrical portion 14. The joining portion 18 may be formed continuously along the circumference of the first semi-cylindrical portion 12, that is, along the side and bottom. Accordingly, it is possible to minimize the leakage of heat to the outside by covering the gap between the joints between the first semi-cylindrical portion 12 and the second semi-cylindrical portion 14, As shown in FIG. 6, a joining portion 18 is formed on the metal foil 20 and the metal foil 20 constituting the first semi-cylindrical portion 12, and the refractory 22 provided on the inside is formed in the same shape The connecting portion 18 is formed.

A joining member 26 for fixing the iron core 20 and the refractory 22 may be further provided at the tip of the first semi-cylindrical portion 12. In this embodiment, the engaging member 26 may be provided at the joint portion 18 at the tip of the first semi-cylindrical portion 12. The joining member 26 may have a structure in which both side ends are bent so as to be fitted to the joining portion 18 protruding outwardly. Thus, when the engaging member 26 is fitted into the abutting portion 18, the bent portions of both side ends clamp the abutting piece 20 and the refractory 22 in the abutting portion 18 and fix it.

The coupling member 26 may further include a hole for fastening a bolt, an anchor, or the like. Corresponding to the position of the hole, a hole is also formed in the refractory 20 and the refractory 22. In this state, when the refractory 20 and the refractory 22 are combined with each other, the engaging member is mounted on the abutting portion 18 and the bolt, the anchor, or the like is fastened through the hole, so that the fixing force can be increased.

The first semicylinder 12 may be provided on the inner circumferential surface and the tip may extend toward the immersion nozzle 110 to divide the inner space of the housing 10. The retention plate 28 does not contact the immersion nozzle 110 and forms a gap between the immersion nozzle 110 and the immersion nozzle 110. It is possible to increase the residence time of the heat in the space inside the housing 10 by the retention plate 28 and to enhance the preheating effect. The retention plate 28 may be formed in a horizontal state. Or the retention plate 28 may be formed to be inclined downward toward the immersion nozzle 110.

Fig. 7 shows the second semicylinder 14. As shown in FIG. 7, the second semicylinder 14 may include a metal foil 20 having an outer shape and a refractory 22 disposed on the inner surface of the metal foil 20 in a half-cut shape. The upper end of the scoop 20 is cut into a semicircular shape so as to be in close contact with the side surface of the immersion nozzle 110. A fastening member for fastening the swing arm 50 to the distal end of the swing arm 56 is formed on the outer surface of the scoop 20. The fastening member may be a structure in which a fitting groove is formed so that the tip of the rotary arm 56 is fitted and can be easily coupled with a bolt or the like. The structure of the fastening member and the fastening structure with the distal end of the rotary arm 56 can be variously modified.

The refractory 22 is formed in a shape corresponding to the refractory 20 and is installed inside the refractory 20. The refractory 22 may be formed by embedding the refractory 22 in a shape corresponding to the refractory 20 and inserting the refractory 22 into the refractory 20 or by attaching the refractory 22 to the inner surface of the refractory 20. The refractory 22 may be any material that can withstand the high temperature inside the foil 20 and minimize heat conduction to the foil 20.

A burner 16 is installed below the second semicylinder 14. 9, the burner 16 may be installed at a position corresponding to the discharge port 112 formed in the lower portion of the immersion nozzle 110 when the housing 10 is installed to surround the immersion nozzle 110 have. Thus, the burner 16 can emit a flame toward the discharge port 112 of the immersion nozzle 110. The flame of the burner 16 flows into the immersion nozzle 110 through the discharge port 112 of the immersion nozzle 110 so that the flame of the burner 16 can be heated as well as the inner peripheral surface of the immersion nozzle 110. As described above, the outer surface and the inner surface of the immersion nozzle 110 are simultaneously heated inside the housing 10, so that the immersion nozzle 110 can be preheated more effectively.

The second semicylinder 14 may be provided on the inner circumferential surface and the tip may extend toward the immersion nozzle 110 to form a gap with the immersion nozzle 110. The retention plate 28 provided in the second semi-cylindrical portion 14 is formed at the same position as the retention plate 28 provided in the first semi-cylindrical portion 12. Therefore, a retention plate 28 is formed in the inner peripheral surface of the immersion nozzle 110 inside the housing 10 in the form of a ring. The retention plate 28 is not in contact with the immersion nozzle 110 and forms a gap with the immersion nozzle 110. Also, although not shown, the second semicylinder 14 may further include a separate engaging member (not shown) for fixing the refractory 22 and the screed 20.

As shown in Fig. 9, the retention plate 28 divides the space inside the housing 10 into two upper and lower spaces. The internal heat of the housing 10 is restricted from rising by the retention plate 28 and flows upward through the gap between the retention plate 28 and the immersion nozzle 110. The burner 16 is installed in the lower portion of the housing 10 and is positioned on the lower space side of the two spaces of the housing 10 divided by the stay plate 28. Thus, the heat generated by the flame of the burner 16 is heated in the submerged nozzle 110 while staying in the lower space defined by the retention plate 28 in the housing 10.

Also, as mentioned above, the housing 10 has a conical cross-sectional structure with a large diameter at the lower end, so that the lower space of the housing 10 is relatively large. Thus, the flame of the burner 16 can stay in the space below the housing 10 for a sufficiently long time. Therefore, the flame of the burner 16 in the housing 10 remains in the lower space, and the residence time of the heat by the flame is increased. As described above, by increasing the residence time of the flame through the burner 16, the preheating effect can be enhanced.

Hereinafter, the operation of the preheating apparatus according to the present embodiment will be described.

The tundish 100 is seated and moved in the tundish car 200. If an equipment trouble or the like occurs and the tundish must wait for a while, the present apparatus installed in the tundish car 200 is driven to preheat the immersion nozzle 110. Therefore, it is possible to prevent the temperature of the immersion nozzle 110 from dropping even in the atmosphere.

When the apparatus is driven, the housing 10, which has been waiting at the bottom of the tundish car 200, is moved toward the immersion nozzle 110 to cover the immersion nozzle 110. The housing 10 is divided into a first semi-cylindrical section 12 and a second semi-cylindrical section 14 and is moved toward the immersion nozzle 110 in accordance with the driving of the respective swinging sections 50 to move the immersion nozzle 110 And are in close contact with each other. When the drive cylinder 58 of the swing unit 50 is contracted and operated, the rotary arm 56 is rotated to move the housing 10 installed on the rotary arm 56 toward the immersion nozzle 110.

9, the first semi-cylindrical body 12 and the second semi-cylindrical body 14 are in close contact with each other to form a single housing 10, which surrounds the immersion nozzle 110. The upper end of the housing 10 is in contact with the side of the immersion nozzle 110, and the side and lower ends surround the immersion nozzle 110 to form an inner space. The burner 16 provided in the second semi-cylindrical portion 14 is located at a position corresponding to the molten metal discharge port 112 formed at the lower end of the immersion nozzle 110.

In this manner, the flame is fired in the space inside the housing 10 by driving the burner 16 in a state where the housing 10 is installed in the immersion nozzle 110. The flame of the burner 16 enters the immersion nozzle 110 through the molten steel discharge port 112 to heat the inner surface of the immersion nozzle 110. The flame of the burner 16 is sprayed to the outside of the immersion nozzle 110 through the opposite molten steel discharge port 112 to heat the outer surface of the immersion nozzle 110.

The flame of the burner 16 injected into the housing 10 is prevented from rising by the retention plate 28 provided in the housing 10 so that the outer surface of the immersion nozzle 110 It will warm up. The heat remaining in the lower space of the housing 10 moves upward through a gap between the retention plate 28 and the immersion nozzle 110 to preheat the upper portion of the immersion nozzle 110.

As described above, the interior of the housing 10 is retained in the space under the housing 10 for a long time by the retention plate 28, so that the effect of preheating the immersion nozzle 110 can be enhanced.

When the immersion nozzle 110 is preheated to a predetermined temperature or more after a certain period of time has elapsed, the burner 16 is extinguished and the swinging parts 50 are driven to separate the housing 10 from the immersion nozzle 110. When the driving cylinder 58 of the swinging part 50 is extended, the rotary arm 56 is rotated and the housing 10 is separated from the immersion nozzle 110 and moved. The moved housing 10 is horizontally disposed below the tundish car 200 and is ready for the next preheating operation.

While the illustrative embodiments of the present invention have been shown and described, various modifications and alternative embodiments may be made by those skilled in the art. Such variations and other embodiments will be considered and included in the appended claims, all without departing from the true spirit and scope of the invention.

10: housing 12: first half cylinder
14: second half cylinder 16: burner
18: bonding portion 20:
22: refractory 24: fastening member
26: engaging member 28: retention plate
50: swing portion 52: bracket
54: hinge shaft 56: rotary arm
58: drive cylinder

Claims (10)

A housing enclosing the immersion nozzle to preheat the immersion nozzle of the tundish seated on the tundish car,
A burner installed in the housing to preheat the immersion nozzle by applying heat to the inside of the housing,
A swinging part installed on the tundish and connected to the housing to move the housing to enclose the swinging nozzle or to separate the swinging part from the swinging part;
Lt; / RTI >
Wherein the housing comprises a first semicircular second semicylinder which is separated in two along the circumferential direction of the immersion nozzle and which is in close contact with each other to surround the immersion nozzle,
A second semi-cylindrical second semicylinder of the housing protruding inwardly along an inner circumferential surface of the first semicircular second semicylindrical tube, the distal end extending toward the immersion nozzle to form a gap with the immersion nozzle, and partitioning the housing into an upper space and a lower space Comprising a retention plate,
Wherein the retention plate is formed in a ring shape on an outer circumferential surface of the immersion nozzle in the housing. delete The method according to claim 1,
Wherein the housing further comprises a joint portion continuously protruding along the first semi-cylindrical tip and covering a joint surface of the second semicircular passage. The method according to claim 1,
Wherein the housing comprises a metal foil forming an outer shape, and a refractory provided on an inner surface of the metal foil. 5. The method of claim 4,
Wherein the housing has a larger diameter toward a lower end thereof. delete The method according to claim 1,
Wherein the burner is located in a lower space of the housing and the housing is disposed at a position corresponding to a molten metal discharge port of the immersion nozzle while the immersion nozzle is wrapped. 8. The method of claim 7,
Wherein the swing portion is installed in each of the first semicircular passage and the second semicylindrical passage so as to move the first semicircular passage second semicylindrical passage. 9. The method of claim 8,
Wherein the swing portion includes a bracket provided at a lower portion of the tundish car, a rotary arm rotatably coupled to the bracket around a hinge axis, a rotary arm provided at one end thereof with a divided portion of the housing, And a drive cylinder connected to the tip for rotating the rotary arm about a hinge axis to move a divided portion of the housing. 10. The method of claim 9,
Wherein the first semicircular passage and the second semicylindrical passage are provided in the swing arms of the respective swing portions, and the first semicircular passage and the second semicircular passage are provided in correspondence with the rotation of the rotary arm, Wherein the second semicylindrical tube is gathered to surround the immersion nozzle or to separate the immersion nozzle from the immersion nozzle.

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