KR101612466B1 - Slag cooling cover and the cooling method using of it - Google Patents

Abstract

The present invention relates to a slag cooling cover and a method to cool slag using the same. The slag cooling cover comprises: a cover unit covering at least a part of an open upper part of a slag port, forming a separation space on an upper part of the slag; at least one or more penetration units which can at least partially penetrate into the slag by being installed in an inner side of the cover unit; and a cooling unit connected by passing through the cover unit and spraying cooling water to the slag. The cooling cover is mounted onto the slag port to cover a break surface of the slag. The slag cooling cover detaches a part of the penetration unit connected to an inner side of the cooling cover, and sprays the cooling water to the slag to rapidly cool the slag in the slag port while the slag is blocked from the outside. In other words, the cooling cover covering the upper part of the slag port comprises: the penetration unit having a bored hole on the slag; and the cooling unit spraying the cooling water to the slag; thereby a slag cooling machine being able to be installed in a narrow space. Moreover, the cooling cover is installed in the slag port to be mounted and separated, and performs and stops the cooling of the slag; thereby the slag cooling covering being able to cool the slag without influencing a movement of the slag port.

Description

Technical Field [0001] The present invention relates to a slag cooling cover and a slag cooling cover using the same,

The present invention relates to a slag cooling cover and a slag cooling method using the slag cooling cover. More particularly, the present invention relates to a slag cooling cover capable of cooling a slag in a slag port in a state where the slag is shut off from the outside, and a slag cooling method using the same.

Generally, a slag generated in a steelmaking process is transferred to a slag yard using a transfer bog into a separately prepared slag port using a facility such as a skimmer. After cooling for some time in the yard, the cooled slag is separated from the slag port by a flap operation which inverts the slag port. Of the separated slag, residual and recovered scrap are recycled, and by-products, such as burnt lime, are reused through secondary manufacturing processes.

At this time, the slag cooling was performed by moving the slag-containing slag port to a position where a cooling water supply device capable of supplying a large amount of cooling water was provided, and spraying cooling water on the slag surface. When the slag is cooled by using such a large amount of cooling water, a mixed state of water and slag becomes a state of dying, and dust, for example, scattering of flour can be prevented at the time of slag disposal.

Such slag cooling progresses slowly from the surface of the slag to the inside of the slag, so that there is a problem that the slag cooling takes much time and cooling water until the slag therein is cooled. For example, conventionally, it takes about 24 hours to cool about 20 tons of slag, and since the cooling water must be injected continuously during this process, the amount of cooling water used is increased and the power consumption of the pump for supplying cooling water also increases .

Conventionally, in order to accelerate the cooling of the slag, perforations are formed from the surface of the slag to the inside of the slag, and the cooling water injected into the slag is easily permeated into the slag, .

However, in the conventional method, since the structure for injecting the cooling water and the structure for forming the perforations in the slag are separately provided, the size of the apparatus required for cooling the slag is increased. As a result, the space occupied by the cooling device is widened and the usability of the space is reduced.

The injection of cooling water into the slag is performed in a state in which the slag is completely exposed to the outside. Therefore, when the slag and the cooling water, which are relatively higher in temperature than the cooling water, come into contact with each other, the harmful vapors generated by the temperature difference between them are scattered to the atmosphere as they are, causing environmental pollution.

KR 1368432 B1 KR 1415832 B1

The present invention provides a slag cooling cover capable of cooling slag even during the movement of the slag port, and a slag cooling method using the slag cooling cover.

The present invention provides a slag cooling cover capable of suppressing and preventing an increase in the size of the apparatus for cooling slag, and a slag cooling method using the same.

The present invention provides a slag cooling cover capable of suppressing scattering of harmful vapors generated during slag cooling into the atmosphere, and a slag cooling method using the slag cooling cover.

A slag cooling cover for cooling slag in a slag port according to an embodiment of the present invention includes a cover unit covering at least a part of an open upper portion of the slag port and forming a spacing space at an upper portion of the slag, And at least one infiltration unit at least partially permeable to the inside of the slag, and a cooling unit connected to penetrate the cover unit and spraying the cooling water to the slag.

The cover unit may include a support frame extending upward from an upper end of the slag port and a cover body connected to an end of the support frame at a position opposite to the slag port to cover the melt surface of the slag .

A path forming part forming a moving section of the penetrating unit is formed on the inner surface of the cover body, the path forming part is formed along the circumference of the cover body, and the penetrating unit is formed in the circumferential direction A of the cover body And a second guide groove formed in a direction intersecting with the first guide groove to form a movement section such that the penetration unit can move in the direction B of the cover body, And the upper end of the infiltration unit may be movably inserted into the path forming portion.

The infiltration unit includes at least one infiltration member extending in the direction intersecting the surface of the slag and capable of being loaded into the slag, and a control unit connected to one end of the infiltration member to adjust the height of the infiltration member can do.

The control unit may include an adjustable adjustable axis extending from one end of the infiltrating member to an upper portion of the infiltrative member, and a driver connected to the upper end of the adjustable axis and providing power for adjusting the length of the adjustable axis.

Wherein at least one of the penetrating member and the adjusting shaft is provided with a penetrating member and a first guide bar extending in the extending direction of the adjusting shaft and the first guide bar is protruded on the inner surface of the adjusting shaft and the penetrating member .

Wherein the cooling unit includes a cooling water diesel tube having one end connected to a through hole formed at the upper center of the cover unit, a cooling water reservoir for supplying cooling water to the cooling water diesel pipe, And may include a dispersing portion that is provided on the rotating shaft to be rotatable.

And a pressure regulating unit connected to the outside of the cover unit so as to communicate with the spacing space to provide a suction force to the spacing space, the pressure regulating unit including a pressure regulating unit, which penetrates the side surface of the cover unit and communicates with the spacing space A pressure regulating pipe and an inhaler connected to an end of the pressure regulating pipe, and a collecting member may be provided at the other end of the pressure regulating pipe.

A temperature sensor for detecting a temperature change of the slag in the slag port, the temperature sensor being disposed in contact with or in contact with at least any one of the slag port, the infiltration unit and the cover unit, And a controller for controlling the operation of the infiltration unit, the cooling unit, the pressure regulating unit and the cover unit according to the change.

The method for cooling slag accommodated in the slag port according to an embodiment of the present invention includes the steps of covering a bath surface of the slag by mounting a cooling cover on the slag port, And a process of injecting cooling water into the slag.

The infiltration unit moves along the circumferential direction A of the slag port or the inside direction B of the slag port in the process of inserting a part of the infiltration unit connected to the inside of the cooling cover into the slag, It is possible to increase the size of the perforations.

In the process of spraying the cooling water with the slag, the slag-like dispersing member can be dispersed so as to collide with the infiltration unit while rotating by the supply force of the cooling water supplied into the cooling cover.

The cooling water impinging on the infiltration unit can be injected into the slag along the surface of the infiltration unit.

According to the slag cooling cover and the slag cooling method using the slag cooling cover according to the embodiment of the present invention, the cooling cover for covering the upper portion of the slag pot includes a penetration unit for forming perforations in the slag and a cooling unit for spraying the cooling water in the slag, The slag cooling device can be installed in a narrow space.

Further, since the cooling cover, including the infiltration unit and the cooling unit, can be mounted and dismounted on the open top of the slag port to perform and stop the cooling of the slag, the cooling cover can be kept in a state of being unaffected by the movement of the slag port The cooling of the slag can be facilitated.

The cooling cover covers the upper portion of the slag port to substantially block the slag from the outside, thereby preventing harmful vapors generated during cooling of the slag from escaping to the outside, thereby preventing environmental pollution.

1 is a sectional view showing a state where a cooling cover according to an embodiment of the present invention is mounted on a slag port.
2 is a view for explaining a cover unit according to an embodiment of the present invention.
3 is a view for explaining a penetration unit according to an embodiment of the present invention;
4 is a view for explaining a cooling unit according to an embodiment of the present invention;
5 is a view showing a state in which a pressure regulating unit according to an embodiment of the present invention is mounted on a cover unit.
6 is a view for explaining a temperature sensor and a controller provided in a cooling cover according to an embodiment of the present invention.
FIG. 7 and FIG. 8 are flow charts and process drawings of a slag cooling method using a cooling cover according to an embodiment of the present invention.

Before describing the embodiments of the present invention in detail with reference to the accompanying drawings, it is to be understood that the invention is not limited to the details of construction and the arrangement of the elements described in the following detailed description or illustrated in the drawings. The invention may be embodied and carried out in other embodiments, and may be carried out in various ways.

Herein, it will be appreciated that the device or component orientation (e.g., "front", "back", "up", "down", "top" Quot ;, "left," " right, "" lateral," and the like) used herein are used merely to simplify the description of the present invention, It will be appreciated that the device or element does not indicate or imply that it should simply have a particular orientation. Also, terms such as " first "and" second "are used herein for the purpose of the description and the appended claims, and are not intended to indicate or imply their relative importance or purpose.

In addition, throughout the specification, when an element is referred to as "including " an element, it means that the element may include other elements, not excluding other elements unless specifically stated otherwise.

Hereinafter, a slag cooling cover according to an embodiment of the present invention will be described with reference to FIGS. 1 to 6. FIG. Here, FIG. 1 is a sectional view showing a state where a cooling cover according to an embodiment of the present invention is mounted on a slag port. 2 is a view for explaining a cover unit according to an embodiment of the present invention. 3 is a view for explaining an infiltration unit according to an embodiment of the present invention. 4 is a view for explaining a cooling unit according to an embodiment of the present invention. 5 is a view showing a state in which the pressure regulating unit according to the embodiment of the present invention is mounted on the cover unit. 6 is a view for explaining a temperature sensor and a controller provided in a cooling cover according to an embodiment of the present invention.

Referring to FIG. 1, a slag cooling cover 1000 according to an embodiment of the present invention is a cover for advancing cooling in a state where nearly all the slag S in the slag port S · P is shut off from the outside , A cover unit (100) for forming a spacing space on the upper part of the slag (S) accommodated in the slag port (S · P), a cover unit (100) installed inside the cover unit (100) And a cooling unit 300 which penetrates through the penetration unit 200 and the cover unit 100 as possible and injects the cooling water C to the slag S. [

The slag port S P is a container for accommodating the slag S when discharging the slag S generated in the molten steel and molten iron charged into the ladle and is provided with an internal space capable of accommodating the slag S It can be manufactured in various shapes. For example, the slag pot 100 is formed with a wall extending upward from a flat or concave bottom. At this time, the wall may be inclined from the bottom to the top to facilitate disposal of the slag (S). Here, the slag cooling cover 1000 of the present invention can be mounted on the upper end of the slag port S · P.

Referring to FIG. 2, the cover unit 100 substantially covers the upper portion of the slag port S · P to substantially block the slag port S · P from the outside, And at least a part of the area of the slag S exposed surface is connected to the end of the support frame 120 at a position facing the slag port S · P, (Not shown).

The cover body 110 covers the upper portion of the slag ports S · P to form a space E between the slag port S · P and the inner wall of the cover body 110. The cover body 110 may have a dome shape in which the height of the cover body 110 increases from the outer portion of the slag port S 占 to the center thereof with respect to the planar surface of the slug port S 占.. At this time, as the length in the height direction of the cover body 110 increases, the size of the space E between the slag port S · P and the cover body 110 can be increased. Thus, a part of the infiltration unit 200 and the cooling unit 300, which will be described later, can be easily separated from the upper part of the slag port S · P. Therefore, although the length in the height direction in which the cover body 110 is formed is not limited, a part of the structure of the infiltration unit 200 and the cooling unit 300, which will be described later, And can be formed in a length that can be arranged.

On the inner surface of the cover body 110, a path forming unit 140 may be formed to form a moving section that can move while at least a part of the penetrating unit 200 is inserted. The path forming part 140 forms a section in which a part of the structure of the penetrating unit 200 is moved by a length formed by extending a groove having a predetermined depth from the inner side surface of the cover body 110 to a direction intersecting the height direction . The path forming unit 140 is formed along the circumference of the cover body 110 and includes a first guide groove 110 that forms a section so that the penetration unit 200 can move in the circumferential direction A of the cover body 110, A second guide groove 142 formed in a direction intersecting the first guide groove 142 and forming a section such that the penetration unit 200 is movable in the direction B of the cover body 110, 144).

The first guide groove 142 is formed at a position spaced a predetermined distance inward from the outermost periphery of the cover body 110 at the inner side of the cover body 110 so that the cover body 110 In the circumferential direction (A). The infiltration unit 200 can move along the circumferential direction A of the cover body 110 through the moving section including the D1 position and the D2 position shown in FIG. The size of the perforations formed can be increased.

The second guide groove 144 may be formed in at least one position of the first guide groove 142 in an inner direction B of the cover body 110. The second guide groove 144 is extended in the direction B of the cover body 110 so that the penetration unit 200 can move to the central region of the slag S in the slag port S · P. That is, the penetration unit 200 can be moved to the position D3, which is the movement section formed by the second guide groove 144. [ The infiltration unit 200 moving along the movement section formed by the second guide groove 144 is positioned closer to the slope port S · P than the movement section formed by the first guide groove 142, Perforations can be formed to a position close to the central region. At this time, the second guide groove 144 forms one movement section from one point of the first guide groove 142 in the direction of the eye B, but the second guide groove 144 forms one or more sections It is possible.

Here, the first guide groove 142 according to the embodiment of the present invention forms a symmetrically separated section with respect to the extension line L1 extending in one direction from the center of the cover body 110, and the second guide groove 144, And forms a symmetrically separated section based on the extension line L1. This is to provide a plurality of infiltration units 200 to be described later, and to form perforations in the slag S while moving the respective infiltration units 200 apart from each other. However, the method in which the path forming unit 140 forms the moving section of the penetrating unit 200 is not limited to the above example, and may be modified to form various sections. The path forming unit 140 may be configured such that the penetration unit 200 allows the cooling water to permeate the inner central portion of the slag S indicating the high temperature of the entire area of the slag S, Can be formed.

The support frame 120 is provided between the cover body 110 and the slag ports S · P so that the cover body 110 is disposed at a position spaced a predetermined distance from the upper end of the slag port S · P 110). One end 124 of the support frame 120 is connected to the upper end of the slug port S · P and the other end 126 is connected to the lower end of the cover body 110. 1, a groove 124 is formed at one end 124 of the support frame 120, and a groove 124 is formed at one end 124 of the support frame 120, But may be connected in a concave / convex shape in which the upper end of the slag port S · P is inserted into the groove of the end 124. Although not shown, the slag ports S and the cover body 110 may be connected to the support frame 120 by applying an adhesive to the respective ends. The support frame 120 can increase the size of the space E between the cover unit 100 and the slag S in the slag pot S · P according to the length of the support frame 120 in the height direction. That is, as the length of the support frame 120 in the height direction increases, the spacing distance E can be increased and the support frame 120 partially performs a role for increasing the spacing distance E, It is possible to suppress or prevent formation of a large dome-shaped slope in order to increase the spacing distance E by using only the slits 110. [

The infiltration unit 200 is installed inside the cover unit 100 to form a perforation in the slag S and extends in the height direction intersecting the surface of the slug S to be charged into the slag S And an adjusting unit connected to one end of the penetrating member 250 to adjust the height of the penetrating member 250. [

The adjusting unit is configured to connect between the penetrating member 250 and the cover unit 100 and includes a length adjustable adjusting shaft 230 and an adjusting shaft 230 which are extended upward from one end of the penetrating member 250, And a driver 210 connected to the upper end and providing power for adjusting the length of the adjustment shaft 230.

The control shaft 230 extends in one direction, and one end of the control shaft 230 is connected to the actuator 210 and the other end of the control shaft 230 is connected to the penetrating member 250. The adjusting shaft 230 is formed of a plurality of shafts so that the length of the extended shaft 230 can be adjusted so that the second adjusting shaft 230b is inserted into the first adjusting shaft 230a and the second adjusting shaft 230b is inserted into the third adjusting shaft 230b, 230c may be at least partially inserted to reduce the length of the adjustment shaft 230. [

The driver 210 is a device that provides power to adjust the length of the adjustment shaft 230. [ At this time, the driver 210 can control the lengths of the first adjusting shaft 230a, the second adjusting shaft 230b, and the third adjusting shaft 230c on the same principle as the piston / cylinder.

Here, the driver 210 of the regulating unit may be inserted into the path forming unit described above. Accordingly, the driver 210 can move the penetrating member 250 along the moving section formed by the path forming section 140 itself, thereby moving the penetrating member 250 along the moving section.

The drive unit 210 is inserted into the path forming unit 140 so that it can not come out of the path forming unit 140. Therefore, That is, the cover unit 100 is formed to have a width W ₂₁₀ that is larger than the widths W ₁₄₂ and W ₁₄₄ of the movement section formed by the path forming unit 140 so that at least a part of the movement section 140 is supported in the path forming unit 140. control shaft 230 may be formed the same as the width W _142, W ₁₄₄ of the mobile section, or to have a small width W _230. The actuator 210 can move along the movement section without exiting the first guide groove 142 and the second guide groove 144 and the adjustment shaft 230 can move along the first guide groove 142 and the second guide groove 144, And can be moved out of the guide groove 144 to move.

The infiltration member 250 is connected to the end of the adjustment shaft 230 and is infiltrated into the slag S when the end of the adjustment shaft 230 is lowered by the operation of the actuator 210. The number of perforations formed in the slag S increases as the number of the penetrating members 250 increases and the amount of the cooling water that penetrates into the slag S when the cooling water C is supplied to the slag pot 100 is increased. (C) is increased. Further, the area of contact between the slag S and the cooling water C is increased, and the slag S is rapidly cooled. Therefore, the penetrating member 250 may be formed such that a plurality of end portions thereof, for example, a fork, are branched. At this time, the ends of the infiltrating member 250 that are branched may have the same length or may have different lengths.

The penetration member 250 and the control shaft 230 may have a first guide bar 270 extending in the extending direction of the penetration member 250 and the control shaft 230.

Referring to FIG. 3B, the first guide bar 270 has a center line extending in the height direction from the center of the width in the horizontal direction, that is, the extending direction of the bottom surface of the slag port S · P And may protrude from one side of at least one of the infiltration member 250 and the control shaft 230 facing the center line.

More specifically, one surface of the infiltration member 250 and the control shaft 230 facing the side wall of the slag port S · P is referred to as an outer surface, and the outer surface of the penetrating member 250 and the control shaft 230 ) Is called the inner side. At this time, the first guide bar 270 is formed at an outer periphery of at least one of the infiltration member 250 and the inner side surface of the control shaft 230, and extends in the extending direction of the infiltration member 250 and the control shaft 230 . When the cooling water C injected into the spacing space E is scattered by the penetrating member 250 or the adjusting shaft 230 and collides with the first guide bar 270 by the cooling unit 300, The cooling water C is guided to the lower end portion of the penetrating member 250 along the guide path formed by the first guide bar 270 to easily penetrate the cooling water C along the penetrating unit 200 into the slag S .

4, the cooling unit 300 penetrates the cover unit 100 from the outside of the cover unit 100 and communicates with the spacing space E to supply the cooling water C to the spacing space E . The cooling unit 300 includes a cooling water diesel pipe 310 having one end connected to the through hole 130 formed at the upper center of the cover unit 100 and a cooling water reservoir 330). The cooling unit 300 includes a dispersing unit 350 disposed in a space below the one end of the cooling water piping 310 in the space E and dispersing the cooling water C supplied to the space E, May be provided. That is, the cooling unit 300 is provided to be connected to the cover unit 100 from the outside of the slug pot S · P to deliver the cooling water C supplied from the outside to the spacing space E, do.

The cooling water reservoir 330 provides a space for storing the cooling water C supplied to the spacing space E and may serve to supply the cooling water C by a certain amount to the cooling water diesel pipe 310 . That is, the cooling water reservoir 330 serves to supply or stop the cooling water C to the slag S, while allowing the cooling water C to be supplied in a proper amount enough to cool the slag S .

The cooling water diesel pipe 310 provides a path through which the cooling water C supplied from the cooling water reservoir 330 flows and the cooling water diesel pipe 310 supplies a cooling water C for the purpose of supplying the cooling water C to the space E The cooling water C is supplied from the upper central portion of the cover body 110 to the slag S so that the slag S can be connected to the cover body 110. [ It is possible to suppress and prevent the cooling water C from being excessively supplied to only one of the positions. The cooling water gas piping 310 is connected to the through hole 130 formed in the center of the cover body 110 in the height direction so as to supply the cooling water C to the center of the spacing space E.

The dispersion unit 350 is disposed directly under the end of the cooling water piping 310 connected to the cover body 110 and disperses the cooling water C supplied through the cooling water piping 310 on the surface of the slag S . The dispersing unit 350 includes a dispersing member 352 disposed in the spacing space E and formed with a cooling water supply hole 354 vertically penetrating the center portion thereof and a second guide bar 352 formed on the dispersing member 352. [ 356).

The dispersing member 352 is formed of a plate having one surface facing the surface of the slug S and is disposed in the spacing space E. [ The dispersing member 352 is connected to the rotating shaft 370 so as to be rotatable in the spacing space E by the pushing force of the cooling water C supplied through the cooling water light pipe 310 and is supported in the through hole 130 . At this time, the dispersing member 352 can rotate clockwise and counterclockwise on the plane, and the direction of rotation of the dispersing member 352 can be changed according to the formation of the second guide bar 356.

The second guide bar 356 is provided on the dispersing member 352 so that the cooling water C supplied onto the dispersing member 352 is provided to generate a force capable of rotating the dispersing member 352, And extend from the center to the outer periphery on the surface of the dispersing member 352 opposite to the end of the cooling water gas piping 310 and may be spaced apart from each other on the dispersing member 352. The second guide bar 356 is formed of a plate which is mounted on the dispersing member 352 so as to be protruded, and the other end of the one end and the outer end of the center part can be connected to the side of the curved line. At this time, the second guide bar 356 may be formed to have a larger value than the thickness of the height h ₃₅₆ dispersing member projecting on the dispersing member 352. The cooling water C supplied to the dispersing member 352 stays at a position close to the second guide bar 356 for a predetermined time on the dispersing member 352 by the projecting height of the second guide bar 356, 2 guide bar 356 can be exerted in a protruding direction of the curve.

The dispersing unit 350 may partially rotate the supply path of the cooling water C before the cooling water C reaches the surface of the slag S so that the cooling water C flows into the cooling water diesel pipe 310, Can be more easily supplied to the entire area of the surface of the slag S than when it reaches the surface of the slag S as soon as it is supplied in the slag S. The dispersing unit 350 sprays the cooling water C on the dispersing member 352 by the rotation of the dispersing member 352. The cooling water C to be sprayed collides with the penetrating unit 200, So that the cooling efficiency of the slag S can be increased.

The cooling cover 1000 formed as described above is connected to the space E outside the cover unit 100 to provide a pressure control unit 400 for providing a suction force to the space E .

6, the pressure regulating unit 400 includes a pressure regulating pipe 410 which communicates with the space E through the side surface of the cover unit 100 and is connected to one end of the pressure regulating pipe 410 And includes an aspirator 430. In addition, a collecting member 450 may be provided at the other end of the pressure control pipe 410. The pressure regulating unit 400 is connected to the cover unit 100 to cool the harmful vapors generated in the spacing space E by the infiltration unit 200 and the cooling unit 300 And can be recovered into a space separated from the outer space of the cover 1000. Therefore, almost all of the harmful vapors generated in the spacing space E are recovered to the independent space without being scattered to the outside, thereby preventing air pollution caused by external scattering of the harmful vapor.

The collecting member 450 may filter the dust contained in the harmful vapor G before the harmful vapor G is sucked into the pressure control pipe 410. Accordingly, dust contained in the harmful vapor can be prevented from accumulating in the pressure control pipe 410, thereby suppressing frequent maintenance of the pressure control pipe 410. Meanwhile, although the collecting member 450 is shown as being formed of a plurality of meshes in the present invention, the collecting member 450 can be formed to collect dust by various methods.

6, the cooling cover 1000 is disposed in contact with or in contact with at least any one of the slag port S P infiltration unit 200 and the cover unit 100 so that the slag ports S P The temperature of the slag S in the cooling unit 300 and the temperature of the slag S detected from the temperature sensor 500 to detect a change in the temperature of the slag S, A controller 600 for controlling the operation of the unit 100 may be provided.

The temperature sensor 500 is provided for measuring the temperature of the slag S and includes a slag port S · P which is influenced by the temperature of the slag S during the cooling of the slag S, 200 and the cover unit 100 so as to sense the temperature change of the slag S. [ That is, the high-temperature heat represented by the slag S is transmitted to the slag port S P, the infiltration unit 200 and the cover unit 100, where the temperature sensor 500 changes as the slag S cools The heat of the slag S can be measured in real time.

The controller 600 controls the operation of the infiltration unit 200, the cooling unit 300 and the cover unit 100 in accordance with the temperature change of the slag S measured from the temperature sensor 500. More specifically, when the temperature of the slag S measured in real time from the temperature sensor 500 is lowered to a temperature at which the temperature of the slag S is normally lowered to discharge the slag S, S and send a signal to stop the operation of the infiltration unit 200 and the cooling unit 300 to stop the supply of the cooling water C. [ A signal is transmitted to the cover separator (not shown) so that the cover unit 100 is separated from the upper portion of the slag port S · P so that the cover unit 100 does not cover the opened upper portion of the slag port S · P .

Meanwhile, the controller 600 may play an opposite role. That is, when the temperature of the slag S is sensed by the temperature sensor 500 at a temperature at which the slag S is required to be cooled, the cover unit 100 is automatically engaged on the slag port S · P The infiltration member 250 of the infiltration unit 200 generates a puncture in the slag S and the cooling unit 300 can cause the cooling water C to be sprayed.

The cooling cover 1000 configured as described above can be mounted on or separated from the upper end of the slag port S · P so that the slag S can be cooled without being disturbed by the movement of the slag port S · P. That is, after the slag port S · P is stopped at a predetermined position, the slag cooling cover 1000 is cooled by the cooling means and the penetration means provided at a predetermined position in a state in which the opened upper portion is exposed to the outside, The cooling cover 1000 supported in the slag port S P forms a perforation in the slag S and the infiltration unit 200 and the cooling unit 100 capable of spraying the cooling water C 300, the infiltration unit 200 and the cooling unit 300 can be operated while moving together with the slag port S · P.

Hereinafter, with reference to FIGS. 7 and 8, a method of cooling the slag S using the slag cooling cover according to the embodiment of the present invention will be described. Here, FIG. 7 is a flowchart showing a slag cooling method according to an embodiment of the present invention. 8 is a process diagram showing a slag cooling method according to an embodiment of the present invention.

The method of cooling slag according to an embodiment of the present invention includes the steps of covering the opened hot water surface of the slag S by mounting the cooling cover 1000 to the slag port S P, A process of inserting and removing a part of the penetration unit 200 connected to the inner side, and a process of injecting cooling water into the slag S.

First, the ladle is placed on a truck using a crane such as a ceiling crane, and the charter is repaired from a charter carrying container, such as a toe-decker, according to the dose determined in the loading ladle mounted on the truck. Subsequently, a degassing operation of the molten metal can be performed, and the slag is formed on the molten metal surface by the degassing operation. The slag located on the bath surface is discharged by using the slag dispenser and received in the slag port S · P (S100). Then, the slag port S · P can be seated and moved on the conveyance truck to move to the yard field for discharging the cooled slag S thereafter.

At this time, the cooling cover 1000 is mounted on the upper end of the slag port S · P to cool the slag S accommodated in the slag port S · P, so that the open bath surface of the slag S is blocked (S110). The cooling cover 1000 is mounted on the slag port S · P so that a space E separated from the outside is formed between the slag S and the cooling cover 1000. A penetration unit 200 mounted on the lower portion of the cooling cover 1000 is provided in the spacing space E and the cooling unit 300 and the pressure regulation unit 400 are connected to the space E .

When the cooling cover 1000 is installed in the slag port S P, a perforation is formed in the slag S using the infiltration unit 200 (S 120). That is, the penetrating member 250 of the infiltration unit 200 can be inserted into the slag S by the adjustment shaft 230, thereby forming a perforation in the slug S. The infiltration unit 200 is installed in the circumferential direction A of the slag port S · P or the inside direction B of the slag port S · P by the path forming unit 140 formed in the cover unit 100, So that the size of the perforations formed in the slag S can be increased.

The cooling unit 300 can inject the cooling water C into the slag S by supplying the cooling water to the space E before or after the perforation is formed in the slag S at step S130. That is, the cooling unit 300 may inject the cooling water C into the slag S at the same time when the infiltration unit 200 forms the perforations in the slug S, The cooling water C may be sprayed in a situation where the slag S has already been punctured. At this time, in the process of injecting the cooling water into the slag S, the dispersing member 352 provided in the spacing space E provided on the slag S is rotated by the pushing force of the cooling water C supplied And the slag S is sprayed from the point where the cooling water C is supplied to the point where the slag S is increased in the outward direction. Since the cooling water C sprayed by the dispersing member 352 can be sprayed to a distance at which it can collide with the infiltration unit 200, the cooling water C can easily flow along the surface of the infiltration unit 200 It can be infiltrated into the slag S.

As the cooling of the slag S progresses, a harmful steam G is generated in the spacing space E due to the temperature difference between the slag S and the cooling water C, (S140).

Thereafter, when the slag S is lowered to a certain temperature by the cooling water C, the operation of the infiltration unit 200, the cooling unit 300 and the pressure regulation unit 400 is stopped to complete the cooling of the slag S (S150). Then, the cooling cover 1000 is separated from the slag port S · P (S160). At this time, the above process is performed by the temperature sensor 500 for measuring the temperature of the slag S in the slag port S P and the infiltration unit 200, the cooling unit 300 and the pressure regulating unit 400 via the controller 600 that can deliver signals to devices that can disconnect the cover unit 100 from the top of the slag ports S P have.

The slag S cooled in the slag port S · P is discharged from the slag port S · P and transferred to the slag recycling processing factory for recycling (S170).

Although the present invention has been described with reference to the accompanying drawings and the preferred embodiments described above, the present invention is not limited thereto but is limited by the following claims. Accordingly, those skilled in the art will appreciate that various modifications and changes may be made thereto without departing from the spirit of the following claims.

S: Slag S · P: Slag port
C: Cooling water 1000: Slag cooling cover
100: cover unit 200: infiltration unit
300: cooling unit 400: pressure regulating unit

Claims (13)

A cover for cooling slag in a slag port,
A cover unit covering at least a part of the open top of the slag port and forming a spacing space at an upper portion of the slag;
At least one infiltration unit provided inside the cover unit and at least partially permeable into the slag;
A path forming unit formed on an inner side surface of the cover body of the cover unit and forming a moving section of the penetrating unit; And
And a cooling unit connected to the cover unit and spraying cooling water to the slag,
The path-
A first guide groove formed along the periphery of the cover body to form a movement section such that the penetration unit is movable in a circumferential direction A of the cover body; And
And a second guide groove formed in a direction intersecting with the first guide groove and forming a movement section such that the penetration unit is movable in the direction B of the cover body,
And an upper end portion of the infiltration unit is movably inserted into the path forming portion. The method according to claim 1,
The cover unit includes:
And a support frame extending upward from an upper end of the slag port,
Wherein the cover body is connected to an end of the support frame at a position opposite to the slag port to cover the melt surface of the slag. delete The method according to claim 1,
The infiltration unit comprises:
At least one penetrating member extending in a direction crossing the surface of the slag and being able to be charged into the slag;
And an adjusting unit connected to one end of the infiltrating member to adjust an elevation height of the infiltrating member. The method of claim 4,
The controller
An adjustable axis extending from one end of the penetrating member to an upper portion thereof, the adjustable axis being adjustable in length; And
And a driver connected to an upper end of the adjustment shaft and providing power for adjusting the length of the adjustment shaft. The method of claim 5,
And a first guide bar extending from the penetrating member and the iron shaft in at least one of the penetrating member and the adjusting shaft,
Wherein the first guide bar protrudes from an inner surface of the adjusting shaft and the penetrating member. The method according to claim 1,
A cooling water diesel tube having one end connected to a through hole formed at an upper center of the cover unit;
A cooling water reservoir for supplying cooling water to the cooling water diesel pipe; And
And a dispersing portion provided directly below and below the coolant durability tube end portion in the spacing space and formed to be rotatable. The method according to claim 1,
And a pressure regulating unit connected to the outside of the cover unit so as to communicate with the spacing space to provide a suction force to the spacing space,
The pressure regulating unit includes a pressure regulating pipe passing through a side surface of the cover unit and communicating with the spacing space; And an inhaler connected to an end of the pressure control tube,
And a collecting member is provided at the other end of the pressure control pipe. The method of claim 8,
A temperature sensor for detecting a temperature change of the slag in the slag port, the temperature sensor being disposed in contact with or in contact with at least any one of the slag port, the infiltration unit and the cover unit; And
And a controller for controlling operation of the infiltration unit, the cooling unit, the pressure regulating unit and the cover unit according to a temperature change of the slag in the slag pot sensed by the temperature sensor. A method for cooling slag contained in a slag port,
A step of mounting a cooling cover on the slag port to cover the bath surface of the slag;
Removing a part of the penetration unit connected to the inside of the cooling cover into the slag;
And injecting cooling water into the slag,
In the process of inserting a part of the penetration unit connected to the inside of the cooling cover into the slag,
Wherein the infiltration unit moves along the circumferential direction (A) of the slag port or the inside direction (B) of the slag port to increase the size of the perforations formed in the slag. delete The method of claim 10,
In the process of spraying the cooling water with the slag,
Wherein the slag-like dispersing member is rotated by a supply force of cooling water supplied into the cooling cover, so that the cooling water is dispersed so as to collide with the infiltration unit. The method of claim 12,
Wherein the cooling water colliding with the infiltration unit is injected into the slag along the surface of the infiltration unit.

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