KR20230151299A - Device for removing dross of snout - Google Patents

Abstract

Provides Snout's dross removal device. The snout dross removal device according to the present invention includes a snout for supplying a strip by passing it into a plating bath, a dross removal unit for removing dross adhering to the outer surface of the snout, and a dross removal unit. It includes a first moving part for moving the snout in the vertical direction.

Description

DEVICE FOR REMOVING DROSS OF SNOUT}

The present invention relates to Snout's dross removal device.

Generally, in a continuous hot dip galvanizing line (CGL: Continuous Galvanizing Line), zinc plating is performed to ensure corrosion resistance of the strip.

As the strip passes through a snout connected to a heating bath in a plating bath containing molten zinc, the iron (Fe) eluted from the strip reacts with the zinc in the plating bath, and through this process, suspended solids are formed inside the plating bath. A dross is formed.

Depending on the location at which these dross are generated inside the plating bath, they are divided into bottom dross formed on the inner lower part of the plating bath, floating dross flowing inside the molten zinc, and on the surface of the molten zinc. It is classified as the top dross formed.

Among these, the upper dross is adhered to the outer wall of the snout when air blowing is performed by an air knife to adjust the plating amount. In this way, the dross adhered to the outer wall of the snout grows and touches the strip or surrounds it. Phenomena such as connection to fixed parts of equipment occur.

In addition, when the dross adhered to the outer wall of the snout comes into contact with the strip, it adheres to the surface of the strip or causes defects by stamping the surface of the strip, thereby reducing the marketability of the strip with complete galvanization.

The present invention seeks to provide a snout dross removal device that can automatically and effectively remove dross attached to the outer wall of the snout when air blowing with an air knife for adjusting the plating amount is performed.

The snout dross removal device according to one embodiment of the present invention is disposed between a plating bath in which molten zinc is stored and a heating furnace, and includes a snout for supplying a strip by passing it into the plating bath, and disposed outside the snout. It may include a dross removal unit for removing dross adhered to the outer surface of the snout.

In addition, the dross removal device of the snout may be installed on the outer surface of the snout and include a first moving part for moving the dross removal part in the vertical direction of the snout.

The dross removal device of the snout is installed on one side of the snout and may include a wave blocking unit to block waves generated when the dross removal unit moves from contacting the strip.

The dross removal unit includes a snout cover movably disposed on the outside of the snout, and a unit installed at the lower end of the snout cover to scrape off dross adhering to the outer surface of the snout as the dross removal unit moves. May include a scraper.

The lower end of the scraper may be placed in contact with the outer surface of the snout.

The first moving part includes a housing installed on one side of the snout, a first screw shaft rotatably coupled to at least one first drive motor installed in the housing, and a snout cover connected to the lower end of the first screw shaft. It may include a support plate supported on one side.

The wave blocking unit is disposed at a set distance on one side of the snout and may include a wave blocking film to block waves generated when the dross removal unit moves up and down and contact with the strip.

The wave barrier may be placed perpendicular to the surface of the molten zinc.

The wave blocking unit is coupled to the wave blocking film and may include a second moving part for moving the wave blocking film in the vertical direction of the molten zinc surface.

The second moving part may immerse the wave blocking film into the molten zinc.

The second moving part includes a second screw shaft supported on a sink roll base installed at the top of the plating bath and rotatably driven by a second drive motor, and rotatably coupled to the second screw shaft and comprising a wave shield and a second screw shaft. It may include a connecting plate for connecting the screw shaft.

According to an embodiment of the present invention, dross attached to the outer wall of the snout can be automatically and effectively removed when air blowing with an air knife for adjusting the plating amount is performed.

Accordingly, the work load can be reduced by eliminating the conventional work of removing stuck dross, safety accidents caused by dross removal work can be prevented in advance, and sticking and growth of dross can be suppressed as much as possible. , can improve the marketability of the strip.

1 is a schematic partial configuration diagram of a snout dross removal device according to an embodiment of the present invention.
Figure 2 is a schematic configuration diagram for explaining the operating state of the snout dross removal device according to an embodiment of the present invention.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described so that those skilled in the art can easily implement the present invention. As can be easily understood by those skilled in the art to which the present invention pertains, the embodiments described below may be modified into various forms without departing from the concept and scope of the present invention. As much as possible, identical or similar parts are indicated using the same reference numerals in the drawings.

The terminology used below is only for referring to specific embodiments and is not intended to limit the invention. As used herein, singular forms include plural forms unless phrases clearly indicate the contrary. As used in the specification, the meaning of "comprising" is to specify a specific characteristic, area, integer, step, operation, element and/or component, and to specify another specific property, area, integer, step, operation, element, component and/or group. It does not exclude the existence or addition of .

All terms including technical and scientific terms used below have the same meaning as those generally understood by those skilled in the art in the technical field to which the present invention pertains. Terms defined in the dictionary are further interpreted as having meanings consistent with the related technical literature and currently disclosed content, and are not interpreted in ideal or very formal meanings unless defined.

Figure 1 is a schematic partial configuration diagram of a snout dross removal device according to an embodiment of the present invention, with strips omitted for convenience of explanation, and Figure 2 is a schematic diagram of a snout dross removal device according to an embodiment of the present invention. This is a schematic diagram to explain the operating status of the loss removal device.

Referring to FIGS. 1 and 2, the snout dross removal device according to an embodiment of the present invention includes a snout 30, a dross removal unit 100, a first moving unit 200, and a wave blocking unit. It may include unit 300.

The snout 30 is disposed between the plating bath 10 in which the molten zinc 11 is stored and the heating furnace (not shown), and is used to prevent the strip 20 from contacting the atmosphere to prevent oxidation of the strip 20. (20) can be supplied by passing it into the plating bath (10).

Additionally, the dross removal unit 100 is disposed on the outside of the snout 30 and can remove dross adhered to the outer surface of the snout 30.

The first moving unit 200 is installed on the outer surface of the snout 30 and can move the dross removal unit 100 in the vertical direction (S direction in FIG. 1) of the snout 30.

In addition, the wave blocking unit 300 is installed on one side of the snout 30 and prevents the waves generated when the dross removal unit 100 by the first moving unit 200 from coming into contact with the strip. It may include a wave blocking unit 300 for blocking.

The snout 30 may be installed inclined at a set angle with respect to the surface of the plating bath 10 so that the strip 20 can effectively pass into the plating bath 10.

The dross removal unit 100 may include a snout cover 110 and a scraper 120.

The snout cover 110 is placed on the outside of the snout 30 to be movable along the vertical direction (S direction in FIG. 1) of the snout 30 and may be installed to surround the snout 30.

In addition, the scraper 120 is installed at the lower end of the snout cover 110 and can scrape off dross adhered to the outer surface of the snout 30 when the dross removal unit 100 moves in the vertical direction.

The snout cover 110 may be formed in a square shape similar to that of the snout 30.

In addition, the snout cover 110 has a size slightly larger than the size of the snout 30 so that it can be easily moved by the first moving part 200. That is, there may be a slight gap between the inner surface of the snout cover 110 and the outer surface of the snout 30.

The scraper 120 is installed at an angle from the outer surface of the snout cover 110 inward, that is, to the outer surface of the snout 30, so that it can effectively scrape and remove dross adhering to the outer surface of the snout 30. It can be.

Accordingly, the lower end (end) of the scraper 120 may be disposed close to or in contact with the outer surface of the snout 30.

The first moving unit 200 can adjust the operation cycle and operation speed depending on the amount of dross adhered to the outer surface of the snout 30.

Additionally, the first moving unit 200 may include a housing 210, a first driving motor 220, a first screw shaft 230, and a support plate 240.

The housing 210 is installed on one side of the snout 30 and may have a square shape, etc.

At least one first drive motor 220 may be installed in the housing 210.

Additionally, the first screw shaft 230 is rotatably coupled to the first drive motor 220 and can be rotated in one direction or the other direction by driving the first drive motor 220.

The support plate 240 is connected to the lower end of the first screw shaft 230 and may be supported on the upper end of one side of the snout cover 110.

A plurality of first screw shafts 230 may be installed at set intervals in the housing 210 to easily move the support plate 240.

In addition, on one side of the snout 30, there is a stopper for stopping the movement of the dross removal unit 100 so that the scraper 120 of the dross removal unit 100 is not excessively immersed in the molten zinc 11. A limit switch (not shown) may be installed.

Additionally, the wave blocking unit 300 may include a wave blocking film 310 and a second moving unit 320.

The wave blocking film 310 is disposed at a set distance on one side of the snout 30, and protects against waves generated when the dross removal unit 100 is moved up and down by the first moving unit 200 and the strip 20. Contact can be blocked.

The wave blocking film 310 is perpendicular to the surface of the plating bath 10 (Y direction in FIGS. 1 and 2) to effectively block waves generated when the dross removal unit 100 moves up and down from contact with the strip. It can be placed as .

In addition, the wave blocking unit 300 is coupled to the wave blocking film 310, and when the dross removal unit 100 moves, the wave blocking film 310 moves in the vertical direction of the surface of the molten zinc 11 (see Figures 1 and 2). It may include a second moving part 320 for moving in the Y direction.

The second moving part 320 moves the wave blocking film 310 to be immersed into the molten zinc 11 of the plating bath 10 for a set length so that the wave blocking film 310 can effectively block the contact between the wave and the strip. You can do it.

The second moving part 320 may include a second screw shaft 323 and a connection plate 325.

The second screw shaft 323 is supported on the sink roll base 40 installed on the upper part of the plating bath 10 and can be rotatably driven by the second drive motor 321.

Additionally, the connection plate 325 is rotatably coupled to the second screw shaft 323 and can connect the wave blocking film 310 and the second screw shaft 323.

A sinking roll 50, a collecting roll 60, and a stabilizing roll 70 may be installed inside the plating bath 10 to change the direction of the strip 20.

Hereinafter, with reference to FIGS. 1 and 2, the operation of Snout's dross removal device according to an embodiment of the present invention will be described.

First, the first drive motor 220 of the first moving unit 200 is driven to rotate the first screw shaft 230 in one direction (e.g., clockwise) and the other direction (e.g., counterclockwise) for a set time. give.

Accordingly, the dross removal unit 100 moves in the vertical direction (of FIGS. 1 and 2) of the surface of the molten zinc 11 of the plating bath 10 along the longitudinal direction of the snout 30 (S direction in FIG. 1). It moves round and round in the Y direction.

That is, as the first screw shaft 230 rotates in one direction, the support plate 240 moves along the vertical direction (inclined direction) of the snout 30 toward the lower part of the snout 30, that is, the plating bath 10 ) moves toward the surface.

Accordingly, the dross removal unit 100 also moves like the support plate 240 and moves below the surface of the molten zinc 11 of the plating bath 10.

At this time, the scraper 120 scrapes the dross attached to the outer surface of the plating bath 10. It is removed by taking it out, and the dross removed by the scraper 120 falls into the inside of the plating bath 10 and is melted by the molten zinc 11.

In addition, as the first screw shaft 230 rotates in the other direction, the support plate 240 moves toward the upper part of the snout 30 along the vertical direction (inclined direction) of the snout 30, that is, toward the plating bath 10. ) moves upward to the surface of the molten zinc (11).

Accordingly, the dross removal unit 100 also moves like the support plate 240 and moves toward the upper part of the snout 30.

In this way, while the scraper 120 of the dross removal unit 100 reciprocates toward the lower or upper part of the snout 30, the dross adhered to the outer surface of the snout 30 can be scraped off and removed. .

And, when the snout cover 110 and the scraper 120 of the dross removal unit 100 move back and forth toward the lower or upper part of the snout 30, waves are generated.

In this way, the generated waves can be blocked from contact with the strip 20 by the wave blocking film 3100.

That is, when the second drive motor 321 is driven when the first drive motor 220 is driven, the second screw shaft 323 moves in one direction (eg, clockwise) due to the drive of the second drive motor 321. It is rotated.

Accordingly, the connection plate 325 coupled to the second screw shaft 323 moves downward (Y direction in FIG. 2) of the second screw shaft 323, so that the wave blocking film 310 is connected to the plating bath 10. ) of molten zinc (11) is dipped below the surface for a set length.

Therefore, since the wave blocking film 310 blocks the waves generated during the reciprocating movement of the dross removal unit 100 and the strip 20, the sink roll 50, the collecting roll 60, and the stabbing The strip 20, which is transferred by changing direction through the rising roll 70, does not come into contact with the wave.

Therefore, when blowing air with an air knife to adjust the plating amount, dross adhering to the outer wall (outer surface) of the snout can be automatically and effectively removed.

Accordingly, the work load can be reduced by eliminating the conventional work of removing stuck dross, safety accidents caused by dross removal work can be prevented in advance, and sticking and growth of dross can be suppressed as much as possible. , can improve the marketability of the strip.

Although the present disclosure has been described through preferred embodiments as described above, the present invention is not limited thereto and various modifications and variations are possible without departing from the scope of the claims described below. Those working in the field will easily understand.

10: Plating bath
20: strip
30: Snout
100: dross removal unit
110: Snout Cover
120: scraper
200: first moving part
210: housing
230: first screw shaft
300: Wave blocking unit
310; wave barrier

Claims (10)

A snout disposed between a plating bath in which molten zinc is stored and a heating furnace, for passing and supplying a strip into the plating bath;
A dross removal unit disposed on the outside of the snout and removing dross adhered to the outer surface of the snout, and
A first moving part installed on the outer surface of the snout and for moving the dross removal unit in the vertical direction of the snout
Snout's dross removal device including. According to paragraph 1,
A dross removal device for a snout, which is installed on one side of the snout and includes a wave blocking unit to block waves generated when the dross removal unit moves from contacting the strip. According to claim 1 or 2,
The dross removal unit,
A snout cover movably disposed on the outside of the snout, and
A dross removal device for a snout, which is installed at the lower end of the snout cover and includes a scraper for scraping off dross adhered to the outer surface of the snout when the dross removal unit moves. According to paragraph 3,
A dross removal device for a snout, wherein the lower end of the scraper is disposed in contact with the outer surface of the snout. According to paragraph 2,
The first moving part,
A housing installed on one side of the snout,
A first screw shaft rotatably coupled to at least one first drive motor installed in the housing, and
A snout dross removal device connected to a lower end of the first screw shaft and comprising a support plate supported on one side of the snout cover. According to clause 5,
The wave blocking unit,
The dross removal device of the snout is disposed at a set distance on one side of the snout and includes a wave blocking film to block waves generated when the dross removal part moves up and down and contact with the strip. According to clause 6,
Snout's dross removal device, wherein the wave shield is disposed perpendicular to the surface of the molten zinc. In clause 7,
The wave blocking unit is coupled to the wave blocking film and includes a second moving part for moving the wave blocking film in the vertical direction of the molten zinc surface. According to clause 8,
Snout's dross removal device, wherein the second moving part immerses the wave blocking film into the interior of the molten zinc. According to clause 9,
The second moving part,
a second screw shaft supported on a sink roll base installed on top of the plating bath and rotatably driven by a second drive motor; and
Snout's dross removal device is rotatably coupled to the second screw shaft and includes a connection plate for connecting the wave shield and the second screw shaft.

Images