KR101504977B1 - Apparatus for preheating - Google Patents

Abstract

The present invention relates to an air conditioner comprising an inner cover, an outer cover and an aspirator, wherein the inner cover is opened at an upper portion thereof, a plurality of flame holes are formed through the side surface of the inner cover, A plurality of suction holes are formed in a side surface of the outer cover, the suction unit is connected to the suction holes to form a preheating device, an immersion nozzle is inserted into the space of the inner cover, Wherein the flame holes and the suction holes formed in the preheater are spaced equidistantly along side surfaces of the inner cover and the outer cover, the suction unit applies a suction force, and the immersion nozzle The preheating flame and gas form a homogeneous flow of air towards the buoyant inhaler towards the space of the inner cover, The preheating device that can be presented to preheat it.

Description

{Apparatus for preheating}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a preheating apparatus, and more particularly, to a preheating apparatus capable of uniformly preheating an object to be processed in a preheating process.

The tundish used in the continuous casting process receives the molten steel taken in the ladle and supplies it to the mold. An immersion nozzle is provided at the bottom of the tundish, and molten steel taken in the tundish is supplied to the mold through the immersion nozzle. The immersion nozzle serves to control the injection flow of molten steel in the process of supplying molten steel to the mold. On the other hand, the molten steel passing through the immersion nozzle can be locally solidified in the immersion nozzle having a temperature relatively lower than the temperature of the molten steel, which causes the stable flow of molten steel in the immersion nozzle to be inhibited. To prevent this, the immersion nozzle is generally subjected to a preheating process before being introduced into the continuous casting process. The immersion nozzle is preheated to a high temperature (about 900 ° C) through a preheating process, and can steadily supply molten steel to the mold.

The preheating of the immersion nozzle proceeds with the preheating of the tundish. The preheating method of the immersion nozzle is a direct preheating method in which a direct flame is applied to the immersion nozzle and an indirect preheating method in which the flame applied to the inside of the tundish is guided to the immersion nozzle to preheat the immersion nozzle to preheat the tundish . In the direct preheating method, it is troublesome to preheat the immersion nozzle by using an external burner separately. In addition, there is a problem in that the preheating efficiency of the region where each flame is interfered is lowered due to the interference of the flame by the external burner and the flame applied inside the turn-around. In general, an indirect preheating method is used for preheating the immersion nozzle.

In order to preheat the immersion nozzle, the continuous casting facility is provided with a preheating device for directing the flame inside the tundish to the immersion nozzle. Generally, the preheating apparatus includes a preheating oven which is arranged to surround the immersion nozzle at the outside of the immersion nozzle and communicates with the immersion nozzle, and a suction fan which is connected to one side of the preheating oven. The preheater drives the suction fan to introduce the preheating flame applied to the interior of the turn-dish into the immersion nozzle. The flame introduced into the immersion nozzle is discharged through a discharge port at the lower end of the immersion nozzle, and in this process, the immersion nozzle is preheated.

However, the conventional preheating apparatus has the following problems. The preheating flame discharged to the discharge port of the immersion nozzle is guided by the flow of the preheating flame along the suction direction of the suction fan. Therefore, by the biased flow of the preheating flame, the temperature distribution in the preheating oven is located in the guiding direction of the preheating flame It is different in the opposite region. For example, when the actual temperature of the region located in the induction direction of the preheating flame is 890 ° C, the temperature in the opposite region is measured at 850 ° C, and the region between the two regions is measured at 830 ° C. The difference in temperature distribution in the preheating oven preheating the immersion nozzle causes the immersion nozzle to have a corresponding distribution of the preheating temperature. When the immersion nozzle is preheated unevenly, the preheating temperature at the end of the preheating of the immersion nozzle changes depending on the position of the immersion nozzle. As a result, during the initial operation of the continuous casting process, stable flow of molten steel passing through the immersion nozzle and supplied to the mold is hindered, which causes stability of the operation of the continuous casting process.

The present invention provides a preheating device capable of uniformly preheating an object to be processed in a preheating process of the object to be processed.

The present invention provides a preheating apparatus capable of uniformly controlling flames or gas flow for preheating an object to be treated.

A preheating apparatus according to an embodiment of the present invention is a preheating apparatus for preheating an article to be processed, the apparatus comprising: an inner cover having a space opened at an upper portion thereof and a plurality of flame holes formed at a side surface thereof; An outer cover which surrounds the outer cover and has a suction hole penetrating the side surface and a path connecting the suction hole and the flame hole; And an inhaler disposed outside the outer cover and connected to the suction hole to communicate with the path.

Wherein the inner cover includes an inner cover body portion forming the space and an inner cover refractory portion formed on an inner surface of the inner cover body portion and the flame hole is formed through the inner cover refractory portion and the inner cover body portion .

The flame holes may be equally spaced along the circumferential direction of the inner cover.

The flame holes may be spaced apart from each other in the vertical direction of the inner cover or may be helically spaced along the periphery of the inner cover side surface.

The inner diameter of the end portion of the flame hole located on the inner side of the inner cover may be larger than the inner diameter of the other end portion of the flame hole.

The inner diameter of the flame hole may gradually change from one end of the flame hole toward the other end.

A thread may be formed on the inner wall of the flame hole.

Wherein the outer cover includes an outer cover body enclosing an outer side of the inner cover and an outer cover refractory portion formed on an inner surface of the outer cover body and the suction hole penetrating the outer cover refractory portion and the outer cover body portion And the outer cover refractory portion may be spaced apart from the inner cover to form the path.

The suction holes may be formed at at least four positions spaced at equal intervals in the circumferential direction of the outer cover.

The suction unit includes a suction pipe connected to the suction hole at an outer side of the outer cover; A connection pipe extending outwardly from a side surface of the outer cover and extending in a circumferential direction of the outer cover, the connection pipe being connected to the suction pipe; A discharge pipe extending from one side of the connection pipe to the outside; And suction means connected to an end of the discharge pipe.

The material to be treated is an immersion nozzle connected to a lower portion of a turn-dish which is operated in a continuous casting facility, and the immersion nozzle is inserted into a space of the inner cover and can communicate with the path.

A flame for preheating the turn-off is applied to the inside of the turn-off, and the flame of the turn-off is moved by the inhaler to pass through the immersing nozzle, the space, and the path.

According to the embodiment of the present invention, it is possible to obtain a preheating device capable of forming the direction of flow of the flame or gas for preheating the object to be processed in a direction desired by the operator.

From this, it is possible to uniformly control the flow of the flame or gas for preheating the object to be processed, thereby uniformly preheating the object to be processed.

For example, when used for preheating an immersion nozzle connected to a tundish operated in a continuous casting process, the preheating device according to an embodiment of the present invention is arranged to surround the immersion nozzle outside the immersion nozzle, And a multi-directional flame hole is formed in the inner cover. The gas heated by the flame or the flame applied to the inside of the tundish through the formed flame hole is uniformly flowed in multiple directions and the immersion nozzle can be uniformly preheated by the uniformly flowing flame or gas .

1 is a schematic diagram of a preheater according to an embodiment of the present invention;
2 is a schematic view of an inner cover according to an embodiment of the present invention;
3 is a schematic view of an outer cover according to an embodiment of the present invention.
4 is a schematic view of an inhaler in accordance with an embodiment of the present invention.
5 is a schematic view of a flame hole in accordance with an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments described below, but may be embodied in various forms. 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. The drawings may be exaggerated in size to illustrate the embodiments, and like reference numbers in the drawings indicate like elements.

2 is a schematic view showing an inner cover according to an embodiment of the present invention. FIG. 3 is a sectional view of an outer cover according to an embodiment of the present invention. FIG. Fig. FIG. 4 is a schematic view showing an inhaler according to an embodiment of the present invention, and FIG. 5 is a schematic view showing a cross section of a flame hole according to an embodiment of the present invention. Here, FIG. 2 (a) is a schematic view showing an inner cover according to an embodiment of the present invention, and FIG. 2 (b) is a schematic view showing an inner cover according to a modified example of the present invention. 5 (a) is a schematic view showing a cross-sectional shape of a flame hole according to an embodiment of the present invention, and Figs. 5 (b) to 5 Fig.

1 to 5, the preheating device is a preheating device for preheating an article 10 to be processed. The preheating device includes a space in which an upper part is opened, an inner cover (not shown) through which a plurality of flame holes 130 are formed, An outer cover 200 which surrounds the inner cover and includes a suction hole 230 penetrating the side surface and a path connecting the suction hole 230 and the flame hole 130, 200 and an inhaler 300 connected to the suction hole 230 and communicating with the path.

Here, the article to be treated 10 may be an immersion nozzle connected to the lower portion of the turn-dish operated in the continuous casting facility. Since the immersion nozzle is a general construction applied to a general continuous casting facility, a detailed description thereof will be omitted. In this embodiment, the object to be treated 10 is an immersion nozzle, but the present invention is not limited thereto. The immersion nozzle may be accommodated in a space provided in the inner cover 100 to be described later, And can be various kinds of treatments that can be preheated by the method.

2, the inner cover 100 includes an inner cover body 110 forming an upper opened space and an inner cover refractory 120 formed on an inner surface of the inner cover body 110. [ . The inner cover body 110 may be formed in the shape of a container having an upper open space. In this embodiment, a cylindrical inner cover body portion 110 having a bottom surface and a side surface formed along the edge of the bottom surface is illustrated. The upper portion of the inner cover body 110 is opened upward, so that the inner cover body 110 can form an open space. The inner cover body 110 has an inner cover refractory portion 120 having a predetermined thickness. A general refractory material which can withstand a high temperature (about 900 ° C) generated in the preheating process of the article 10 may be applied to the inner cover refractory portion 120. Accordingly, the inner cover body portion 120 can protect the inner cover body portion 110 from the high temperature generated during the preheating process of the object to be processed 10. The size of the inner cover 100 is formed corresponding to the size of the object 10 disposed in a space provided inside the inner cover 100. That is, the inner diameter of the inner cover 100 may be larger than the outer diameter of the article 10 to be processed. In addition, the length of the side surface of the inner cover 100 in the up and down direction may be larger than the preheating area of the target object 10 to be processed. The object to be processed 10 may be disposed in a space provided inside the inner cover 100. The inner cover 100 may further include opening / closing means (not shown) for covering the upper portion of the inner cover 100. The opening / closing means (not shown) serves to cover between the side of the inner cover 100 at the upper part of the inner cover 100 and the outer side of the object 10 disposed in the space of the inner cover 100. The shape of the inner cover body 110 thus formed is not particularly limited and may be formed in various shapes. For example, the inner cover body 110 may be formed in the shape of a polyhedron having an open space at the top.

The flame hole 130 is formed through the inner cover refractory portion 120 and the inner cover body portion 110. The formed flame holes 130 may be equally spaced along the circumferential direction of the inner cover 100. 2 (a), the flame holes 130 may be spaced apart from each other in the vertical direction of the inner cover 100 or may be spaced apart from each other on the side surface of the inner cover 100 as shown in FIG. 2 (b) Can be spaced apart spirally along the perimeter. In the present embodiment, the inner cover 100 is divided into a first row of flame holes at six positions spaced apart from each other in the circumferential direction of the inner cover 100 and a second row of flame holes spaced below the first row of flame holes, (See Fig. 2 (a)). In the modified example of the present embodiment, the flame holes 130, which are arranged in an imaginary line formed in a spiral shape along the circumference of the inner cover 100 and are equally spaced apart from each other in the circumferential direction of the inner cover 100 The inner cover 100 is formed (see Fig. 2 (b)). However, the present invention is not limited thereto, and the flame holes 130 may be formed to have various arrangements at positions spaced equidistantly in the circumferential direction of the inner cover 100. At this time, the flame holes 130 may be formed in at least four positions spaced apart from each other in the circumferential direction of the inner cover 100, and the flow of flame or high temperature fluid formed by the inhaler 300, which will be described later, 10 in the vertical direction. As described above, in the present embodiment, the arrangement of the flame holes 130 can be uniformly spaced along the circumference of the inner cover 100. The flow of the flame or gas, which will be described later, flowing through the flame hole 130 in the space provided in the inner cover 100 to the path of the outer cover 200 described later, may have multiple directions. Thus, a flowing flame or gas can flow uniformly as it passes through each flame hole 230.

As shown in FIGS. 1 and 5, the flame holes 130 may be formed such that the inner diameters of the ends of the flame holes 130 located on the inner side of the inner cover 100 are larger than the inner diameters of the other end portions. The inner diameter of the flame hole 130 gradually changes from one end to the other end of the flame hole 130. That is, the flame hole 130 may be formed to have a trapezoidal shape in cross section as shown in FIG. 5 (a). The flow rate of the flame or gas passing through the flame hole 130 can be controlled by the shape of the cross section of the flame hole 130. [ The flame hole 130 according to the present embodiment can serve as a converging nozzle when viewed from the direction of flow of the flame or gas, and the flow of the flame or gas passing through the flame hole 130 The speed and flow rate are controlled. Although the flame hole 130 having a trapezoidal cross section is illustrated in the present embodiment, the shape of the cross section of the flame hole 130 may be variously formed. For example, the flame holes 130 may be formed so that the inner diameters of both ends of the flame holes 130 are the same, as shown in Fig. 5 (b). In addition, the inner wall of the flame hole 130 may be formed to have a spiral shape as shown in Figs. 5 (b) and 5 (d). The flame or gas flowing through the flame hole 130 may be rotated and flow along the inner wall of the flame hole 130 according to the operation method of the preheater according to the present embodiment, The flow can be formed more smoothly.

3, the outer cover 200 includes an outer cover body 210 surrounding the outer side of the inner cover 100 and an outer cover body 220 formed on the inner side of the outer cover body 210 ). The shape and size of the outer cover body 210 may have a shape and size corresponding to the shape and size of the inner cover 100 disposed on the inner side of the outer cover 200. In this embodiment, an outer cover body portion 210 having the shape of a cylindrical container having an upper opened space is illustrated. That is, the outer cover body 210 is formed with a bottom surface of the disk-shaped outer cover body 210, and is formed along the edge of the bottom surface of the outer cover body 210, . The outer cover body 210 is formed so as to extend from the upper end of the side surface of the outer cover body 210 in a direction crossing the side of the outer cover body 210 toward the inner cover body 110, An upper surface is formed. However, the present invention is not limited thereto, and the outer cover 200 may be formed in a polygonal shape to cover a predetermined area on the side surface of the inner cover 100 where the flame holes 130 formed in the inner cover 100 are disposed. The size of the bottom surface of the outer cover body 210 may be larger than the size of the bottom surface of the inner cover body 110. [ The vertical length of the side surface of the outer cover body 210 corresponds to the size of the side surface of the inner cover body 110 so that the inner cover body 110 can be seated inside the outer cover mud body 210 . The inner cover 100 may be disposed inside the outer cover 200 and the side surface of the outer cover body 210 may be spaced from the side surface of the inner cover body 110 to have a spacing space. The upper surface of the outer cover body 210 is formed to cover the above-described spacing space. That is, the end of the upper surface of the outer cover body 210 protrudes to contact the outer surface of the upper end of the inner cover body 110. An outer cover refractory portion 220 having a predetermined thickness is formed on the inner surface of the outer cover body portion 210. The thickness of the formed outer cover refractory portion 220 is formed to be smaller than the distance between the inner cover body 110 and each side of the outer cover body 210 so that the outer cover body 210 and the inner cover 210, A spaced space may be formed between each side of the body 110. Thus, the outer cover refractory portion 220 is separated from the inner cover 100 to form a path. The flame or gas described later can flow through the formed path. The outer cover 200 and the inner cover 100 are formed so as to surround the article 10 to be processed from the outside of the article to be processed 10 and form the double covers 100 and 200 to form the article 10 ) Can be efficiently preheated. That is, the preheating apparatus according to the present embodiment forms a double cover, and the flame hole 130 formed in the inner cover 100 of the double cover and the arrangement of a suction hole 230 described later formed in the outer cover 200 And the number in the desired arrangement and number. This makes it possible to form a velocity fluctuation of the flame and gas in the path provided between the inside of the inner cover 100 and the inner cover 100 and the outer cover 200, .

The suction holes 230 may be formed through the outer cover refractory portion 220 and the outer cover body portion 210. The suction holes 230 may be formed at at least four positions spaced at equal intervals in the circumferential direction of the outer cover 200. That is, the number of the suction holes 230 is formed corresponding to the suction amount of the target flame or gas. For example, the suction hump 230 may be formed at six positions spaced equidistantly in the circumferential direction of the outer cover 200. In this embodiment, the suction holes 230 are formed at four positions spaced equidistantly in the circumferential direction of the outer cover 200. The diameter of the suction hole 230 is formed corresponding to the flow amount of the desired flame and gas. The flame or gas flowing through the path provided in the outer cover 200 may have a desired flow rate and a flow rate. The position of the suction hole 230 in the vertical direction is not particularly limited. The suction hole 230 formed on the side surface of the outer cover 200 in the vicinity of the region where the flame hole 130 of the inner cover 100 is formed is illustrated in this embodiment. As described above, in the present embodiment, the arrangement of the suction holes 230 is arranged to be uniformly spaced along the periphery of the outer cover 200, so that flames or gas flowing along the path of the outer cover 200 are supplied to the suction holes 230 As shown in FIG.

4, the suction unit 300 includes a suction pipe 310 connected to the suction hole on the outer side of the outer cover 200, a suction pipe 310 spaced outward from the side of the outer cover 200, A connection pipe 320 connected to the suction pipe 310 and a discharge pipe 330 extending outwardly from one side of the connection pipe 320 and suction means connected to the end of the discharge pipe 330 340, such as a suction motor. The suction pipe 310 is attached to the suction hole 230 formed in the outer cover body 210 and communicates with the outer cover 200 and is extended outside by a predetermined length. A connection pipe 320 is formed to connect the ends of the plurality of suction pipes 310 connected to the respective suction holes 230. In this embodiment, the connection pipe 320 having an annular shape is illustrated, and the end of each suction pipe 310 is connected to the connection pipe 320 to communicate with the suction pipe 310. The discharge pipe 330 is installed on one side of the connection pipe 320 and communicates with the connection pipe 320, and is extended outward by a predetermined length. Suction means 340 is mounted at the end of the formed discharge tube 330. However, the configuration and shape of the inhaler 300 are not limited to the above-described components and shapes. A configuration and a configuration capable of sucking a flame or gas flowing through the suction hole 230 by connecting the suction holes 230 formed in the outer cover 200 and the suction means 340 provided in the suction device 300, As shown in FIG. In this embodiment, a suction motor is exemplified as the suction means 340. [ However, the suction means 340 may be applied with various means, such as an air pump, capable of sucking a flame or gas flowing through the pipe.

The operation method of the preheating device in which the immersion nozzle connected to the lower portion of the turn-down by the above-described preheating device is preheated is as follows. An immersion nozzle is inserted into a space provided in the inner cover (100) to communicate with a path provided in the outer cover (200). A flame is applied to preheat the tundish inside the tundish. At this time, the suction means 340 of the preheating device according to the present embodiment is driven to apply a suction force to the preheating device. The gas whose temperature is raised by the flame or flame applied to the interior of the turn-dish by the suction means 340 is sucked through the path of the immersion nozzle, the inner cover 100, and the outer cover 200. At this time, the immersion nozzle is preheated by the flame or gas being sucked. Here, the flame or gas is uniformly flowed outward from the vertical axis of the immersion nozzle by the flame holes 130 uniformly spaced along the side surface of the inner cover 100. Specifically, a flame or a gas contacts or flows uniformly in each region of the immersion nozzle in the direction rotating about the central axis of the immersion nozzle. That is, the preheating device operated as described above can uniformly preheat the immersion nozzle compared to the conventional case. Thereafter, continuous casting operation is carried out subsequently. The immersion nozzle uniformly preheated by the preheating apparatus according to the present embodiment can prevent the local temperature drop of the molten steel inside the injection additive immersion nozzle of the molten steel. In addition, it is possible to effectively prevent the damage of the immersion nozzle and the deterioration of the quality of the molten steel due to uneven preheating as in the prior art. That is, the immersion nozzle can guide the path of the molten steel stably to the mold.

Although the embodiment of the present invention has exemplified the case of preheating the immersion nozzle of the turn-dish, which is operated in the continuous casting process, it can also be applied to other preheating processes. It should be noted that the above-described embodiments of the present invention are for explanation purposes only, and are not for the purpose of limitation. It is to be understood that various modifications may be made by those skilled in the art without departing from the scope of the present invention.

100: inner cover 130: flame hole
200: outer cover 230: suction hole
300: inhaler 310: suction pipe
340: suction means

Claims (12)

A preheating device for preheating an object to be processed,
An inner cover having a top open space and a plurality of flame holes formed through the side surface;
An outer cover which surrounds the outer cover and has a suction hole penetrating the side surface and a path connecting the suction hole and the flame hole; And
And an inhaler disposed outside the outer cover and connected to the suction hole to communicate with the path,
Wherein the path is formed such that the outer cover is spaced apart from the inner cover,
The inhaler includes:
A suction pipe connected to the suction hole outside the outer cover;
A connection pipe extending outwardly from a side surface of the outer cover and extending in a circumferential direction of the outer cover, the connection pipe being connected to the suction pipe;
A discharge pipe extending from one side of the connection pipe to the outside; And
And suction means connected to an end of the discharge pipe.
The method according to claim 1,
Wherein the inner cover includes an inner cover body portion forming the space and an inner cover refractory portion formed on an inner surface of the inner cover body portion,
Wherein the flame hole is formed through the inner cover refractory portion and the inner cover body portion.
The method of claim 2,
Wherein the flame holes are equally spaced along the circumferential direction of the inner cover.
The method of claim 3,
Wherein the flame holes are spaced apart in the vertical direction of the inner cover or spaced apart in a spiral manner along the circumference of the inner cover side.
The method of claim 2,
Wherein the flame hole is formed such that an inner diameter of an end portion of the flame hole located on the inner side of the inner cover is larger than an inner diameter of the other end portion.
The method of claim 5,
Wherein the flame holes gradually change in inner diameter from one end of the flame holes toward the other end.
The method of claim 2,
Wherein a thread is formed on the inner wall of the flame hole.
The method according to claim 1,
Wherein the outer cover includes an outer cover body enclosing an outer side of the inner cover and an outer cover refractory formed on an inner side of the outer cover body,
Wherein the suction hole is formed through the outer cover refractory portion and the outer cover body portion,
Wherein the outer cover refractory portion is spaced apart from the inner cover to form the path.
The method of claim 8,
Wherein the suction holes are formed at at least four positions spaced equidistantly in the circumferential direction of the outer cover.
delete The method according to any one of claims 1 to 9,
The object to be treated is an immersion nozzle connected to the lower portion of the turn-dish operated in the continuous casting equipment,
Wherein the immersion nozzle is inserted into the space of the inner cover and communicates with the path.
The method of claim 11,
A flame for preheating the turn-off is applied to the inside of the turn-off time,
And the flame of the turn-off is moved by the suction unit to pass through the immersion nozzle, the space, and the path.

Images