KR100783081B1 - Washer for submerged nozzle - Google Patents

Abstract

A washer for a submerging nozzle is provided to improve workability by taking impurities, such as alumina or non-metal materials, off a discharging hole of the submerging nozzle by spraying inert gas to the impurities. A washer(100) for a submerging nozzle includes a housing(110), an expandable unit(150), a rod(152), a nozzle body(120), a spraying hole(130), and a pipe(132). The housing embraces an outer diameter of the submerging nozzle. The expandable unit is embedded in the housing for lifting the nozzle body. The rod connects the expandable unit and the nozzle body. The nozzle body is located on a lower part of the housing, is connected to the expandable unit through the rod, and is lifted by an operation of the expandable unit. The spraying hole is connected to the pipe for being supplied with inert gas from a storage tank and sprays the inert gas to a discharging hole of the submerging nozzle.

Description

Immersion Nozzle Cleaning Device {WASHER FOR SUBMERGED NOZZLE}

1 is a cross-sectional view showing the installation of a conventional immersion nozzle and tundish.

Figure 2 is a perspective view showing the immersion nozzle cleaning apparatus according to the present invention.

3 is an exploded perspective view of the immersion nozzle cleaning apparatus according to the present invention.

4 is a plan view of the immersion nozzle cleaning apparatus according to the present invention.

5 is a cross-sectional view showing a state in which the immersion nozzle cleaning apparatus according to the present invention is installed in a tundish.

<Description of Symbols for Main Parts of Drawing>

10: tundish 20: mold

30: sliding gate 40: immersion nozzle

50: lift 100: dipping nozzle cleaning device

110 housing 120 nozzle body

130: injection hole 140: holder

150: expansion and contraction unit 160: drive motor

The present invention relates to an immersion nozzle cleaning device, and more particularly, the discharge port is installed in the immersion nozzle of the continuous casting device to adhere to the discharge hole formed in the immersion nozzle to grow and close the discharge hole to remove the alumina and non-metallic deposits. It relates to an immersion nozzle cleaning plant for injecting inert gas into the furnace.

In general, the continuous casting device is composed of a facility for continuously producing a cast of a constant size by receiving the molten steel produced in the steel mill and transported to the ladle to the mold. 1 is a cross-sectional view showing the installation of a conventional immersion nozzle and tundish.

Referring to the drawings, a ladle installed in a ladle turret is filled with molten steel in which impurities are removed and chemical composition is adjusted, and the molten steel in the ladle is made through a cylindrical firebrick shroud nozzle. Supply to Tundish. The tundish 10 is for continuously supplying molten steel from the ladle to the mold 20 so as to continuously produce the slab. The tundish 10 is provided with a slide gate 30 and an immersion nozzle under the tundish 10. 40 is installed to minimize contact with the atmosphere when molten steel is supplied to the mold 20.

The immersion nozzle 30 as described above is a medium for supplying the molten steel of the tundish 10 to the mold 20, and serves to insulate the molten steel, stabilize the molten steel in the mold, and block the contact between the molten steel and the atmosphere. Perform. To this end, the immersion nozzle 30 has a substantially upright tube shape and a flow path 42 through which molten steel flows therein, and an inner bottom surface of the immersion nozzle 30 is located below the mold 40. The molten steel is closed so as to prevent the molten steel from being directly discharged, and a molten steel discharge port 44 is formed on the side surface (periphery of the outer diameter of the immersion nozzle) perpendicular to the direction of the flow path 42.

In addition, a locking protrusion 46 is formed at an upper outer diameter of the immersion nozzle 40, and the locking protrusion 46 is seated on a holder 60 that is lifted and lifted by a lift 50 installed below the tundish 10. do. In other words, the holder 50 is integrally fixed to the lower portion of the tundish 10 or integrally fixedly supported to the sliding gate 30 as shown in the drawing to surround the upper outer diameter of the immersion nozzle 40. Ascended).

A seating groove 62 is formed in the holder 60, and the lift 50 is lifted and operated in a state in which the locking protrusion 46 of the immersion nozzle 40 is seated in the seating groove 62. The upper surface of the immersion nozzle 40 located in the contact with or close to the sliding gate 30, the discharge hole of the immersion nozzle 40 in a state where the upper surface of the immersion nozzle 40 is in close contact with the sliding gate (30) 44 is positioned to draw into the mold 20. When the molten steel is supplied from the tundish 10 to the mold 20 in the above state, the lower part of the immersion nozzle 40 (at least the outlet of the immersion nozzle) is positioned to be immersed in the molten surface.

Accordingly, the sliding gate 30 is operated to supply the molten steel of the tundish 10 to the flow passage 42 of the immersion nozzle 40, and the molten steel flowing along the flow passage 42 is discharged through the discharge port 44. Discharged into the mold 20. When molten steel is supplied into the mold 20 through the discharge hole 44 of the immersion nozzle 40 for a predetermined time as described above, the discharge hole 44 of the immersion nozzle 40 is in a state of being immersed in the molten surface. The molten surface is sprayed with a mold flux to separate and float the alumina and non-metallic inclusions contained in the molten steel supplied to the mold 20, and the alumina and the non-metallic inclusions adhere to the discharge hole 44 of the immersion nozzle 40. Will grow.

As described above, the alumina and the non-metallic deposit fixedly growing at the discharge hole 44 of the immersion nozzle 40 close the discharge hole 44 as the continuous casting becomes longer, thereby causing a change in the molten steel discharge amount supplied to the mold 20. Since the drift occurs in the molten steel supplied to the mold 20 through the discharge port 44, it interferes with the uniform formation of the solidification shell and affects the quality of the cast steel. Therefore, the operator uses a stick to fix the alumina to the discharge port of the immersion nozzle. And non-metallic deposits were removed.

The present invention is to solve the above problems, to provide an immersion nozzle cleaning apparatus that can actively remove the alumina and non-metallic inclusions fixedly grown in the discharge port of the immersion nozzle to improve the work efficiency therefrom. have.

According to the technical idea of the present invention for achieving the above object, a housing supported by a holder on which the immersion nozzle is mounted and surrounding the outer diameter of the immersion nozzle, and located in the lower portion of the housing to extend the longitudinal direction of the immersion nozzle from the housing. It is achieved by an immersion nozzle cleaning apparatus including a nozzle body connected to the rod that is stretched toward and away, and injection holes formed in the nozzle body for injecting inert gas toward the discharge port of the immersion nozzle.

Here, the housing is preferably supported by the holder to have a shape that is bisected along the longitudinal direction of the immersion nozzle and to rotate relative.

The holder further preferably includes a seating portion for winding the upper outer diameter of the immersion nozzle and a base for supporting the arm extending from each of the bisected housings to be rotatable.

It is also preferred that each arm extending from the housing is integrally formed with the gear and meshed with relative rotation.

And the injection angle of the inert gas injected from the injection hole is preferably the same as the molten steel discharge angle discharged through the discharge port of the immersion nozzle.

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

Figure 2 is a perspective view showing the immersion nozzle cleaning apparatus according to the present invention, Figure 3 is an exploded perspective view of the immersion nozzle cleaning apparatus according to the present invention. Referring to the drawings, the immersion nozzle cleaning apparatus 100 according to the present invention, the housing 110 surrounding the outer diameter of the immersion nozzle, and the nozzle body to be elevated in the longitudinal direction of the immersion nozzle in the lower portion of the housing 110 120 and injection holes 130 formed in the nozzle body 120 to inject an inert gas toward the discharge port of the immersion nozzle.

The housing 110 is positioned to surround the outer diameter of the immersion nozzle. The housing 110 has a semi-circular shape that is bisected in the longitudinal direction of the immersion nozzle, and has a nozzle body positioned below the housing 110. The stretching unit 150 is installed to elevate 120. The expansion and contraction unit 150 is configured to slide the piston in the cylinder by hydraulic or pneumatic bar, one end of the piston is fixed to the rod 152 is formed to extend outside the housing.

In order to operate the expansion and contraction unit 150 installed in the housing 110, a flow path 154 is formed outside the housing 110 so that hydraulic pressure or pneumatic pressure can be transmitted to the inside of the cylinder, and the flow path 154 is formed of a fluid or the like. It is connected to a compressor (not shown) that pressurizes the gas and supplies it to the expansion and contraction unit 150.

In addition, the arms 112a and 112b integrally formed with the respective housings 110a and 110b are formed to have a predetermined length behind the bisected housings 110a and 110b, and the gears 114a are formed on the arms 112a and 112b. , 114b are integrally formed (hereinafter referred to as arm gears) so that the arms 112a and 112b extending from each of the housings 110a and 110b are engaged with each other.

In the above description, the housing 110 has a semicircular shape that is bisected in the longitudinal direction of the immersion nozzle and is positioned to surround the outer diameter of the immersion nozzle. However, in some cases, the housing 110 is not bisected. It may have a hollow shape and be formed so that it can be inserted and mounted from the lower part of the immersion nozzle.

The nozzle body 120 is positioned below the housing 110 and connected to the rod 152 extending below the housing 110 to be immersed by the operation of the stretchable part 150 installed in the housing 110. It is installed to move up and down along the longitudinal direction of the nozzle. The nozzle body 120 is formed to surround the lower outer diameter of the immersion nozzle similar to the housing 110, the nozzle body (120a, 120b) is installed in each of the bisected housing (110a, 110b) and each nozzle body ( 120 and 120b, the injection hole 130 for injecting the inert gas toward the discharge port of the immersion nozzle is formed.

In other words, the nozzle body (120a, 120b) is made of a refractory material that can sufficiently withstand the heat emitted from the molten steel, has a shape of a plate surrounding the lower outer diameter of the immersion nozzle. As shown in the drawing, a stripping window 122 is formed in which a portion of the inside of the plate is hollow, and a side end of the stripping window 122 is sprayed to inert gas toward the discharge port of the immersion nozzle. The pores 130 are formed. For example, if the molten steel discharge angle of the discharge port of the immersion nozzle is inclined downward 15 degrees, the inert gas injection angle of the injection hole formed in the nozzle body is inclined upward 15 degrees toward the molten steel discharge port.

The stripping window 122 is formed so that an operator can check the state of the alumina and the non-metallic deposits fixedly grown at the outlet of the immersion nozzle, and the alumina is fixed to the outlet of the immersion nozzle by the inert gas injected from the injection hole 130. And non-metallic deposits are dropped out through the stripping window.

Here, the stripping window 122 is not limited to a substantially rectangular shape as shown in the drawing, and may be a shape corresponding to the shape of the discharge port of the immersion nozzle. In addition, the injection hole 130 formed at the side end of the stripping window 122, is not limited to the side end of the stripping window 122, may be formed around the stripping window along the side end of the stripping window 122 in some cases. have. At this time, the injection hole formed around the stripping window 122 is preferably formed to face the discharge port of the immersion nozzle.

In addition, the injection hole 130 is connected to a conduit 132 to which an inert gas is supplied, and the conduit 132 is connected to a storage tank (not shown) in which pressurized inert gas is stored. At this time, a valve (not shown) for controlling the supply of the inert gas is installed on the conduit 132 to control the supply of the inert gas in accordance with the state of the alumina and the non-metallic deposit fixedly grown at the discharge port of the immersion nozzle.

In some cases, the heating wire on the conduit 132 connected to the injection hole 130 so that the inert gas injected toward the discharge hole of the immersion nozzle through the injection hole 130 can be injected in a heated state to a predetermined temperature (Not shown) may be provided.

Each of the bisected housings 110a and 110b is supported to rotate relative to a holder 140 that is lifted and lifted by a lift installed at a lower portion of the tundish, and the holder 140 has a side surrounding the upper outer diameter of the immersion nozzle. An arm 112a extending from each of the bisected housings 110a and 110b and a seating portion 142 having a shape of an open ring and having a seating groove 144 on which a locking protrusion formed on an upper outer diameter of the immersion nozzle is seated. , 112b) consists of a base 146 which is rotatable.

4 is a plan view of the immersion nozzle cleaning apparatus according to the present invention. Referring to the drawings, the base 146 is provided with thrust bearings 148a and 148b for supporting the arms 112a and 112b extending from the housings 110a and 110b in the axial direction. Any arm gear 114a or 114b meshed with relative rotation is installed in the base 146 to mesh with the gear 162 of the drive motor 60.

Accordingly, when the drive motor 160 is rotated, any one of the arm gears 114a or 114b meshed with the gear 162 of the drive motor 160 may have the thrust bearings 148a and 148 as the central axis. A translational movement is performed to cover or spread the upper outer diameter of the immersion nozzle.

In other words, arms 112a and 112b extend from the housings 110a and 110b to the base 146, and the arms 112a and 112b are provided with arm gears 114a and 114b to the base 146. It is installed to be rotatable in each of the installed thrust bearings 148a and 148b and the arm gears 114a and 114b are engaged to rotate relative to each other. The gear 162 rotating by the drive motor 160 is engaged with the arm gear 114a or 114b. In addition, the base 146 is fixed to a lift for elevating the holder 140, according to the operation of the lift the holder 140 is lifted and the housing 110 installed so as to rotate relative to the holder 140 also holder ( In accordance with the elevation of 140, the immersion nozzle is moved up and down in the longitudinal direction.

The operation of the immersion nozzle cleaning apparatus 100 according to the present invention having the configuration as described above will be described based on FIG. 5.

5 is a cross-sectional view showing a state in which the immersion nozzle cleaning apparatus according to the present invention is installed in a tundish. Referring to the drawings, the immersion nozzle cleaning apparatus 100 according to the present invention is installed in the lower portion of the tundish 10, the holder 140 is in the lift 50 installed in the lower tundish 10 It is fixedly installed. The lift 50 is fixedly fixed to the lower portion of the tundish 10 or integrally fixed to the sliding gate 30 as shown in the figure.

When the locking projection 46 of the immersion nozzle 40 is seated in the seating groove 144 of the holder 120, the drive motor 160 is operated to operate the base of the holder 140 from the respective housings 110a and 110b. Rotate either arm gear 114a or 114b extending to 146. Accordingly, the arm gears 114a and 114b rotate relative to each other, and each of the arms 112a and 112b integrally formed with the arm gears 114a and 114b rotates the thrust bearings 148a and 148b about the center axis thereof. 110a and 110b are rotated to surround the upper outer diameter of the immersion nozzle 40.

When the housings 110a and 110b are positioned to surround the upper outer diameter of the immersion nozzle 40 as described above, the lift 50 operates to bring the upper surface of the immersion nozzle 40 into close contact with the sliding gate 30. The discharge port 44 of the immersion nozzle 40 is introduced into the mold 20. In addition, the expansion and contraction unit 150 installed in each of the housings 110a and 110b is operated to raise the nozzle body 120 to a height such that it is not immersed in the molten surface.

When the immersion nozzle 40 is mounted on the holder 140, the molten steel is supplied from the tundish 10 to the mold 20, and the sliding gate 30 according to the molten surface height of the molten steel supplied to the mold 20. By controlling the opening degree of the immersion nozzle 40, the discharge port 44 is immersed in the molten surface. Then, when molten steel is supplied into the mold 20 through the discharge hole 44 of the immersion nozzle 40 for a predetermined time, the alumina and non-metallic inclusions contained in the molten steel are separated and floated by a mold flux sprayed onto the molten surface. It grows firmly at the discharge port 44 of the 40.

Alumina and non-metallic deposits fixedly grown at the discharge holes 44 of the immersion nozzle 40 prevent the molten steel discharge, thereby closing the discharge holes 44 of the immersion nozzle 40 or generating drift in the molten steel supplied to the mold 20. In this case, supply of molten steel is stopped by controlling the opening degree of the sliding gate 30.

When the supply of molten steel is stopped, the dipping nozzle 40 is operated in the state in which the immersion nozzle 40 is drawn out of the mold 20 to operate the expansion and contraction part 150, particularly the stripping window 122 of the nozzle bodies 120a and 120b. The injection hole 130 formed in the lower portion of the nozzle body 120a to the height to inject the inert gas toward the discharge port 44. In addition, the inert gas pressurized through the injection hole 130 is injected toward the discharge hole 44 of the immersion nozzle 40 to remove the alumina and the non-metallic deposits fixed to the discharge hole 44.

The alumina and non-metallic deposits removed from the outlet 44 of the immersion nozzle 40 by the pressurized inert gas are dropped out of the mold 20 through the stripping window 122 formed in the nozzle bodies 120a and 120b. When the operator confirms the presence or absence of alumina and non-metallic inclusions in the discharge hole 44 of the immersion nozzle 40 through the stripping window 122, the immersion nozzle 40 is introduced into the mold 20 to continuously cast. Will proceed.

The immersion nozzle cleaning device as described above can effectively perform the removal of the alumina and non-metallic deposits made manually by the operator, thereby improving work efficiency.

On the other hand, the present invention is not limited only to the embodiments described above, but can be modified and modified within the scope not departing from the gist of the present invention, it should be seen that such modifications and variations are included in the technical idea of the present invention. do.

For example, the articulated link may be installed in place of the arm and the arm gear installed to rotate relative to the base to translate the bisected housing so as to surround or spread the outer diameter of the immersion nozzle.

The immersion nozzle cleaning apparatus according to the present invention can be removed by spraying a pressurized inert gas toward the alumina and non-metallic inclusions fixedly grown at the discharge port of the immersion nozzle, thereby improving work efficiency.

Claims (5)

A housing supported by a holder on which the immersion nozzle is mounted and surrounding the outer diameter of the immersion nozzle; A nozzle body positioned at a lower portion of the housing and connected to a rod that extends from the housing toward the longitudinal direction of the immersion nozzle; Immersion nozzle cleaning apparatus including a spray hole formed in the nozzle body for injecting an inert gas toward the discharge port of the immersion nozzle. The immersion nozzle cleaning apparatus according to claim 1, wherein the housing is supported by a holder to have a shape divided into two in the longitudinal direction of the immersion nozzle and to rotate relatively. The holder according to claim 2, The seating portion surrounding the upper outer diameter of the immersion nozzle, And a base for supporting the arm extending from each of the bisected housings to be rotatable. The immersion nozzle cleaning apparatus according to claim 3, wherein each of the arms extending from the housing is integrally formed with the gear and engaged with each other. The immersion nozzle cleaning apparatus according to claim 1, wherein an injection angle of the inert gas injected from the injection hole is the same as the molten steel discharge angle discharged through the discharge port of the immersion nozzle.

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