KR102406984B1 - Floating dross processing system of snout and its gas injection apparatus - Google Patents

Abstract

The present invention relates to a Snout suspended solids removal system capable of rapidly and cleanly removing suspended solids generated in a galvanizing tank and a gas injection device thereof, wherein a steel plate progressing space through which a steel plate passes is formed therein, and a snout body formed in a shape that surrounds the interface as a whole so as to discharge suspended substances generated at the interface between the accommodated tangent surface and the steel plate to the outside; and a gas injection device that injects a high-pressure inert gas to rapidly and forcibly discharge the suspended material in a direction away from the steel plate.

Description

Floating dross processing system of snout and its gas injection apparatus

The present invention relates to a system for removing suspended substances of Snout and a gas injection device thereof, and more particularly, to a system for removing suspended substances from Snout and gas therefor, which can quickly and reliably remove suspended substances generated in a galvanizing tank. It relates to the injection device.

In general, a method of forcibly discharging molten zinc and floating matter in the snorkel by simply adding a discharge duct or a pump to the left and right sides of the snorkel without installing a dam in the snorkel has been widely used.

This conventional method has a problem in that excessive generation of ash due to the vaporization of molten zinc in the snorkel occurs, and suspended substances are introduced into the snorkel immersed in the galvanizing bath or the molten metal that flows along the steel plate. Due to the natural flow of zinc, suspended solids could not be discharged in the left and right lateral directions, and so-called suspended solids remained, such as being stagnated or stacked around the steel plate, and there was a problem in that the suspended solids discharge performance was greatly deteriorated.

In order to solve these existing problems, in the prior art, a dam of the snout was added in the form of having a certain height and width in the center of the snorkel to create a flow flow in the front and left and right lateral directions of the snorkel, As a result, the ejection capacity could be partially improved.

However, this conventional dam method is still insufficient to suppress the vaporization of molten zinc, so a nozzle is installed in the direction before the snorkel to suppress vaporization by forcibly spraying gas on the surface of the steel sheet.

This method is called a Humidifier system, and although the vaporization of molten zinc on the surface of the snorkel dam is reduced by the Humidifier system, the dam is caused by the reaction of inert gas with molten zinc. Ash and floating dross generated on the surface of the dam adhere to the surface of the dam structure due to the temperature difference between the galvanizing bath and the snorkel and grow into a larger solid material to reduce the flow There was a problem in that the discharge performance was greatly reduced because the rotational load was increased due to the large interference, and the dross and molten zinc adhered to the propeller surface of the pump system.

Korean Patent Registration No. 10-0742915

The present invention is to solve various problems, including the above problems, by installing a round inner dam portion and a corresponding radial nozzle on an elliptical ring-shaped ring-type pipe body to prevent overflow on the surface of the inner dam portion. ) to forcibly speed up the flow to prevent flow obstruction or vaporization of molten zinc This can be done quickly, and through this, it is possible to greatly improve the discharge performance by discharging more quickly without giving time for floating substances to stick to the surface of the inner dam and snout. An object of the present invention is to provide a system for removing suspended solids of Snout and a gas injection device thereof, which can simplify level maintenance, increase the use cycle of equipment, and significantly reduce maintenance and repair costs. However, these problems are exemplary, and the scope of the present invention is not limited thereto.

In a system for removing suspended substances of Snout according to the spirit of the present invention for solving the above problems, a steel plate progressing space through which a steel plate passes is formed therein, and suspended substances generated at the interface between the molten metal accommodated in the plating bath and the steel plate are removed from the outside. a snout body formed in a shape that surrounds the interface as a whole so as to be discharged into and a gas injection device that injects a high-pressure inert gas to rapidly and forcibly discharge the suspended material in a direction away from the steel plate.

In addition, according to the present invention, the gas injection device is installed to be spaced apart from the hot water surface by a distance, and is formed in a ring shape surrounding the steel plate progress hole so that the steel plate can pass through, and is a rectangular ring long in the longitudinal direction as a whole. a ring-shaped pipe body formed in a shape; A plurality of radial nozzles installed on the ring-shaped pipe body, installed at an angle of injection with respect to the hot water surface, and arranged in a forward, backward, left, and right direction radially so that the inert gas can be sprayed in a forward, backward, left, and right radial shape in a direction away from the steel plate; and a supply pipe connected to the ring-shaped pipe body and supplying the inert gas to the inside of the ring-shaped pipe body.

In addition, according to the present invention, the radial nozzle, at least one front nozzle installed in the front portion of the ring-shaped pipe body; at least one rear nozzle installed in the rear portion of the ring-shaped pipe body; at least one left nozzle installed on the left side of the ring-shaped pipe body; and at least one right nozzle installed on the right side of the ring-shaped pipe body.

In addition, according to the present invention, the front nozzle may include: a left induction nozzle installed at a left inclination angle so that the suspended matter can be discharged in the left direction of the snout body based on the progress center line of the steel plate; and a right induction nozzle installed at a right inclination angle so that the suspended matter may be discharged in the right direction of the snout body based on the progress center line of the steel plate.

In addition, according to the present invention, the left nozzle includes a plurality of left radiation nozzles radially formed to face the curved left inner dam portion of the snout body, and the right nozzle includes: It may include a;

In addition, according to the present invention, the supply pipe may include: a left supply pipe connected to the left side of the ring-shaped pipe body; and a right supply pipe connected to the right side of the ring-shaped pipe body.

Further, according to the present invention, the plating bath is a zinc plating bath in which molten zinc is accommodated, and the inert gas may include a WET nitrogen component.

In addition, according to the present invention, the snout body is formed in a shape surrounding the steel plate progressing space, and the left and right sides are rounded, and the height of at least the molten metal is higher than the molten metal so that the floating material passes through and the molten metal remains. an inner dam unit installed as and a shape surrounding the inner dam to accommodate the floating material that has passed the inner dam, and the floating material is discharged to the outside through the left duct (left pump) and the right duct (right pump) It may include; an outer guide portion in which the floating material discharge passage is formed on the left and right, respectively.

On the other hand, the gas injection device of the suspended matter removal system of Snout according to the spirit of the present invention for solving the above problems is installed to be spaced apart from the hot water surface by a distance, and a ring surrounding the steel plate progress hole so that the steel plate can pass through a ring-shaped pipe body formed in the shape of a rectangular ring shape long in the longitudinal direction as a whole; A plurality of radial nozzles installed on the ring-shaped pipe body, installed at an angle of injection with respect to the hot water surface, and arranged in a forward, backward, left, and right direction radially so that the inert gas can be sprayed in a forward, backward, left, and right radial shape in a direction away from the steel plate; and a supply pipe connected to the ring-shaped pipe body and supplying the inert gas to the inside of the ring-shaped pipe body.

In addition, according to the present invention, the radial nozzle, at least one front nozzle installed in the front portion of the ring-shaped pipe body; at least one rear nozzle installed in the rear portion of the ring-shaped pipe body; at least one left nozzle installed on the left side of the ring-shaped pipe body; and at least one right nozzle installed on the right side of the ring-shaped pipe body.

According to some embodiments of the present invention made as described above, an overflow flow on the surface of the inner dam part is prevented by installing a round inner dam part and a corresponding radial nozzle on the elliptical ring-shaped ring-shaped pipe body. By forcibly and quickly, it is possible to prevent flow disturbance or vaporization of molten zinc, and by inclining the angle of the radial nozzle in the direction away from the steel plate, it is possible to speed up the movement of suspended matter in the left and right ducts (left and right pumps). Through this, it is possible to greatly improve the discharge performance by discharging more quickly without giving time for floating substances to stick to the inner dam and snout surfaces. It can be done easily and has the effect of greatly reducing maintenance and repair costs by increasing the use cycle of the equipment. Of course, the scope of the present invention is not limited by these effects.

1 is a partial perspective perspective view illustrating a system for removing suspended solids of a snout and a gas injection device thereof according to some embodiments of the present disclosure;
FIG. 2 is a plan view showing a gas injection device of the suspended matter removal system of the snout of FIG. 1 .
3 is a cross-sectional view showing a gas injection device of the suspended solids removal system of the snout of FIG. 1 .

Hereinafter, several preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Examples of the present invention are provided to more completely explain the present invention to those of ordinary skill in the art, and the following examples may be modified in various other forms, and the scope of the present invention is as follows It is not limited to an Example. Rather, these embodiments are provided so as to more fully and complete the present disclosure, and to fully convey the spirit of the present invention to those skilled in the art. In addition, in the drawings, the thickness or size of each layer is exaggerated for convenience and clarity of description.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described with reference to the drawings schematically illustrating ideal embodiments of the present invention. In the drawings, variations of the illustrated shape can be envisaged, for example depending on manufacturing technology and/or tolerances. Accordingly, embodiments of the spirit of the present invention should not be construed as limited to the specific shape of the region shown in the present specification, but should include, for example, changes in shape caused by manufacturing.

1 is a partial perspective view showing a suspended solids removal system 100 of a snout and a gas injection device 20 thereof according to some embodiments of the present invention, and FIG. 2 is a suspended solids removal system of the snout of FIG. 1 . It is a top view which shows the gas injection device 20 of 100, and FIG. 3 is a cross-sectional view which shows the gas injection device 20 of the suspended solids removal system 100 of the snout of FIG.

1 to 3 , the system 100 for removing suspended solids of a snout according to some embodiments of the present invention may largely include a snout body 10 and a gas injection device 20 . have.

For example, as shown in FIGS. 1 to 3 , the snout body 10 has a steel plate progressing space through which the steel plate 1 passes therein, and includes the hot water surface F1 accommodated in the plating bath 2 and the It may be a kind of structure for inducing the suspended matter 3 that is formed in a shape that surrounds the interface F2 as a whole so that the suspended matter 3 generated at the interface F2 of the steel plate 1 can be discharged to the outside. .

Here, the plating bath 2 may be a zinc plating bath in which molten zinc is accommodated, and the inert gas G may include a WET nitrogen component.

In contrast to dry nitrogen, the WET nitrogen may refer to nitrogen containing moisture, but is not limited thereto, and various types of inert gases may be applied.

In addition, the base plating tank 2 is not necessarily limited thereto, and all plating tanks accommodating various types of molten metal may be applied.

More specifically, for example, as shown in FIGS. 1 to 3 , the snout body 10 is formed in a shape surrounding the steel plate progress space, and the left inner dam part 11a and the right inner dam part ( 11b) is formed in a round shape, and the suspended material 3 passes through and the molten metal remains. The inner dam part 11 is installed at a height of at least the molten metal level or higher, and the floating material 3 that exceeds the inner dam part 11 is formed in a shape surrounding the inner dam portion 11 to accommodate It may include an outer guide part 12 in which suspended material discharge passages P1 and P2 are formed on the left and right sides, respectively, so as to be possible.

Therefore, since the left inner dam portion 11a and the right inner dam portion 11b of the inner dam portion 11 are formed in a round shape, suspended matter can be rapidly discharged in a radial form from both corners of the steel plate 1 and the stagnant area can be further reduced than the rectangular shape.

In addition, for example, as shown in FIGS. 1 to 3 , the gas injection device 20 is inert at high pressure so that the suspended material 3 can be rapidly forcedly discharged in a direction away from the steel plate 1 . It may be a device for injecting the gas (G).

More specifically, for example, as shown in FIGS. 1 to 3 , the gas injection device 20 is installed to be spaced apart from the hot water surface F1 by a separation distance D, and the steel plate 1 is A ring-shaped pipe body 21 that is formed in a ring shape surrounding the steel plate progress hole H so that it can pass through, and is formed in a rectangular ring shape elongated in the longitudinal direction as a whole, and the ring-shaped pipe body 21 is installed, and the A plurality of installed inclined at a spraying angle A with respect to the hot water surface F1 and arranged in a forward, backward, left, and right radial direction so that the inert gas G can be sprayed in a forward, backward, left, and right radial shape in a direction away from the steel plate 1 . A radial nozzle 22 and a supply pipe 23 connected to the ring-shaped pipe body 21 and supplying the inert gas G to the inside of the ring-shaped pipe body 21 may be included.

Here, the supply pipe 23 includes a left supply pipe 23-1 connected to the left side of the ring-shaped pipe body 21 and a right supply pipe 23-2 connected to the right side of the ring-shaped pipe body 21. It is possible to smoothly supply gas in both the left and right directions.

Therefore, the high-pressure inert gas (G) supplied to the ring-shaped pipe body 21 through the supply pipe 23 can be injected in a direction away from the steel plate 1 by the radial nozzle 22, By using the flow of the inert gas G, the suspended material 3 may quickly overflow the inner dam portion 11 .

Here, as shown in FIGS. 2 and 3, the radial nozzle 22 of the suspended solids removal system 100 of the snout according to some embodiments of the present invention is installed in a plurality of 360 degrees front and rear, left and right, in all directions. At least one front nozzle (22a) installed in the front part of the ring-shaped pipe body (21), at least one rear nozzle (22b) installed in the rear part of the ring-shaped pipe body (21), and the It may include at least one left nozzle 22c installed on the left side of the ring-shaped pipe body 21 and at least one right nozzle 22d installed on the right side of the ring-shaped pipe body 21 .

Here, for example, as shown in FIGS. 2 and 3 , in the front nozzle 22a, the suspended material 3 moves to the snout body 10 based on the center line L of the steel plate 1 . ), the left induction nozzle 22a-1 installed at a left inclination angle K1 and the floating material 3 installed at a left inclination angle K1 to be discharged in the left direction of the It may include a right induction nozzle (22a-2) installed at a right inclination angle (K2) so as to be discharged in the right direction of the snout body (10).

More specifically, for example, the left nozzle 22c includes a plurality of left radiation nozzles radially formed to face the curved left inner dam portion 11a of the snout body 10, and the right The nozzle 22d may include a plurality of right radiating nozzles that are radially formed to face the curved right inner dam portion 11b of the snout body 10 .

Accordingly, it is possible to more rapidly overflow the suspended matter 3 by minimizing the distance between the round inner dam portions 11a and 11b and the left and right radiating nozzles.

Therefore, the round inner dam portion 11 and the corresponding radial nozzle 22 are installed in the elliptical ring-shaped pipe body 21 to overflow the inner dam portion 11 from the surface. ) to forcibly speed up the flow to prevent flow obstruction or vaporization of molten zinc, and by tilting the angle of the radial nozzle 22 in a direction away from the steel plate, floating in the left and right ducts (left and right pumps) It is possible to move the material quickly, and through this, it is possible to greatly improve the discharge performance by discharging more quickly without giving time for the floating material to stick to the surface of the inner dam and snout, and the surface of the inner dam unit 11 By improving the cleanliness, it is possible to easily manage the operation and maintain the level of the hot water, and it is possible to greatly reduce the maintenance and repair costs by increasing the use cycle of the equipment.

Meanwhile, the present invention may include the gas injection device 20 of the suspended solids removal system 100 of the snout.

The gas injection device 20 of the suspended solids removal system 100 of the snout according to some embodiments of the present invention is installed to be spaced apart from the hot water surface F1 by the separation distance D, and the steel plate 1 is A ring-shaped pipe body 21 that is formed in a ring shape surrounding the steel plate progress hole H so that it can pass through, and is formed in a rectangular ring shape elongated in the longitudinal direction as a whole, and the ring-shaped pipe body 21 is installed, and the A plurality of installed inclined at a spraying angle A with respect to the hot water surface F1 and arranged in a forward, backward, left, and right radial direction so that the inert gas G can be sprayed in a forward, backward, left, and right radial shape in a direction away from the steel plate 1 . A radial nozzle 22 and a supply pipe 23 connected to the ring-shaped pipe body 21 and supplying the inert gas G to the inside of the ring-shaped pipe body 21 may be included.

In addition, for example, the radial nozzle 22 includes at least one front nozzle 22a installed in the front part of the ring-shaped pipe body 21 and at least one installed in the rear part of the ring-shaped pipe body 21 . of the rear nozzle 22b, at least one left nozzle 22c installed on the left side of the ring-shaped pipe body 21, and at least one right nozzle 22d installed on the right side of the ring-shaped pipe body 21. may include

Here, the configuration and role of the gas injection device 20 is the same as that of the gas injection device 20 of the suspended matter removal system 100 of the snout according to some embodiments of the present invention described above. can do. Therefore, a detailed description will be omitted.

Although the present invention has been described with reference to the embodiments shown in the drawings, which are merely exemplary, those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

1: steel plate
2: plating bath
3: suspended matter
10: Snout body
11: inner dam part
11a: left inner dam portion
11b: right inner dam portion
12: outer guide part
13: left duct
14: right duct
F1: noodle soup
F2: boundary
G: inert gas
D: separation distance
H: Steel plate progress hole
20: gas injection device
21: ring-shaped pipe body
22: radial nozzle
22a: front nozzle
22b: rear nozzle
22c: left nozzle
22d: right nozzle
A: spray angle
23: supply pipe
23-1: Left supply pipe
23-2: right supply pipe
L: Progression centerline
K1: Left inclination angle
K2: Right inclination angle
22a-1: left induction nozzle
22a-2: right induction nozzle
P1, P2: Suspended matter discharge passage
100: Snout's suspended solids removal system

Claims (10)

a snout body having a steel plate progress space through which the steel plate passes therein, and formed in a shape that surrounds the interface as a whole so as to discharge suspended substances generated at the interface between the hot water surface accommodated in the plating bath and the steel plate to the outside; and
a gas ejection device for ejecting a high-pressure inert gas so as to quickly and forcibly eject the suspended matter in a direction away from the steel plate;
The gas injection device,
a ring-shaped pipe body installed to be spaced apart from the hot water surface by a spaced distance, formed in a ring shape surrounding the steel plate progress hole so that the steel plate can pass, and formed in a rectangular ring shape elongated in the longitudinal direction as a whole;
A plurality of radial nozzles installed on the ring-shaped pipe body, installed at an angle of injection with respect to the hot water surface, and arranged in a forward, backward, left, and right direction radially so that the inert gas can be sprayed in a forward, backward, left, and right radial shape in a direction away from the steel plate; and
a supply pipe connected to the ring-shaped pipe body and supplying the inert gas to the inside of the ring-shaped pipe body;
Including, Snout's suspended solids removal system. delete The method of claim 1,
The radial nozzle,
at least one front nozzle installed in the front part of the ring-shaped pipe body;
at least one rear nozzle installed in the rear portion of the ring-shaped pipe body;
at least one left nozzle installed on the left side of the ring-shaped pipe body; and
at least one right nozzle installed on the right side of the ring-shaped pipe body;
Including, Snout's suspended solids removal system. 4. The method of claim 3,
The front nozzle is
a left induction nozzle installed at a left inclination angle so that the suspended matter can be discharged in a left direction of the snout body based on a progress center line of the steel plate; and
a right induction nozzle installed at a right inclination angle so that the suspended matter can be discharged in a right direction of the snout body based on the progress center line of the steel plate;
Including, Snout's suspended solids removal system. 4. The method of claim 3,
The left nozzle is
A plurality of left radiation nozzles formed in a radial shape to face the curved left inner dam portion of the snout body;
The right nozzle is
A system for removing suspended solids of a snout, including a; a plurality of right radiating nozzles radially formed to face the curved right inner dam portion of the snout body. The method of claim 1,
The supply pipe is
a left supply pipe connected to the left side of the ring-shaped pipe body; and
a right supply pipe connected to the right side of the ring-shaped pipe body;
Including, Snout's suspended solids removal system. The method of claim 1,
The plating bath is a zinc plating bath in which molten zinc is accommodated,
wherein the inert gas comprises a WET nitrogen component. The method of claim 1,
The snout body is
an inner dam part formed in a shape surrounding the steel plate progress space, having left and right sides rounded, and installed at a height of at least the hot water surface so that the floating material can pass through and the molten metal can remain; and
It is formed in a shape surrounding the inner dam to accommodate the floating material that has passed the inner dam, and left so that the floating material can be discharged to the outside through the left duct (left pump) and the right duct (right pump). and an outer guide portion in which a floating material discharge passage is formed on the right side, respectively;
Including, Snout's suspended solids removal system. a ring-shaped pipe body installed to be spaced apart from the hot water surface by a separation distance, formed in a ring shape surrounding the steel plate progress hole so that the steel plate can pass, and generally formed in a long rectangular ring shape in the longitudinal direction;
A plurality of radial nozzles installed in the ring-shaped pipe body, inclined at a spraying angle with respect to the hot water surface, and disposed in a forward, backward, left, and right direction so that the high-pressure inert gas can be sprayed in a forward, backward, left, and right radial shape in a direction away from the steel plate. ; and
a supply pipe connected to the ring-shaped pipe body and supplying the inert gas to the inside of the ring-shaped pipe body;
Containing, the gas injection device of the suspended solids removal system of Snout. 10. The method of claim 9,
The radial nozzle,
at least one front nozzle installed in the front part of the ring-shaped pipe body;
at least one rear nozzle installed in the rear portion of the ring-shaped pipe body;
at least one left nozzle installed on the left side of the ring-shaped pipe body; and
at least one right nozzle installed on the right side of the ring-shaped pipe body;
Containing, the gas injection device of the suspended solids removal system of Snout.

Images