KR101642907B1 - Nozzle and Flushing Method for Cooling medium Pipe - Google Patents

Abstract

The present invention relates to a nozzle for spraying a cooling medium to an object to be processed, the nozzle having a body extending in one direction and injecting a cooling medium at one end thereof, the other end thereof being opened, And a nozzle cap coupled to the other open end of the body and capable of opening and closing the inlet, wherein the cleaning operation of the cooling medium supply pipe It is possible to prevent the foreign matter from flowing into the nozzles of the nozzle, thereby facilitating maintenance of the equipment.

Description

[0001] The present invention relates to a method for cleaning a nozzle and a cooling medium supply pipe,

The present invention relates to a cleaning method of a nozzle and a cooling medium supply pipe, and more particularly, to a cleaning method of a nozzle and a cooling medium supply pipe that prevent foreign matter from flowing into the nozzle during a cleaning operation of the cooling medium supply pipe.

In general, the continuous casting facility is a facility to continuously cast liquid molten steel into a solid phase without defects and to supply the molten steel through a ladle containing refined molten steel and an injection nozzle connected to the ladle. A mold for initially solidifying molten steel received from the tundish into a predetermined shape and a plurality of rollers provided at a lower portion of the mold and having a plurality of rollers for guiding the cooling while cooling the unfused cast steel.

At this time, the spray nozzle provided in the segment mixes the cooling water and the air into the cast steel through which the rollers pass. The continuous and uniform spraying of a certain amount of cooling water during the cooling process of the cast steel using the spray nozzle greatly affects the quality of the cast steel. However, various kinds of sludge may flow into the pipe for supplying the cooling water to the spray nozzle, or water may be generated.

In the spray nozzle, an orifice for controlling the flow rate of the cooling water is installed according to the casting speed. The sludge and the water of the pipe are introduced into the spray nozzle together with the cooling water to lower the permeability of the orifice or clog the orifice. Therefore, the main part is unevenly cooled due to defective cooling water spraying, and the quality of the cast steel is deteriorated.

Therefore, conventionally, a cleaning operation for removing sludge and water in the cooling water pipe has been performed. That is, the cleaning liquid is supplied into the piping to circulate the inside of the piping to remove the sludge or water trapped in the piping. However, as the cleaning liquid including the sludge or the water droplet is directly introduced into the spray nozzle, the sludge or the water contained in the cleaning liquid has a problem of blocking the orifice of the spray nozzle. In addition, the cleaning liquid containing sludge or water droplets is directly discharged through the spray nozzle, thereby causing a problem of polluting the environment of the workplace.

KR 10-1007402 B1

The present invention provides a method of cleaning a nozzle and a cooling medium supply pipe that can prevent foreign matter from flowing into a nozzle during a cleaning operation.

The present invention provides a method of cleaning a nozzle and a cooling medium supply pipe capable of improving the quality of a casting.

The present invention relates to a nozzle for spraying a cooling medium to an object to be processed, the nozzle having a body for spraying a cooling medium at one end thereof, the other end thereof being opened and a movement path for a cooling medium being formed therein, And a nozzle cap coupled to the other open end of the body and opening / closing at least one of the cooling medium inlet and the movement path.

The nozzle cap includes at least one of a first blocking portion capable of blocking the cooling medium inlet and a second blocking portion capable of blocking the movement path.

Wherein the first blocking portion includes a head portion having a size larger than a diameter of the opening portion formed at the other end of the body, and a head portion connected to the head portion and insertable into the opening portion and extending in one direction, Wherein the body portion has an inlet hole through which a cooling medium is introduced, and which can communicate with the inlet of the cooling medium.

The nozzle cap includes a filter provided in the inlet hole for filtering foreign substances in the cooling medium.

And an orifice disposed in a movement path inside the body and disposed between the nozzle cap and one end of the body.

The second blocking portion includes a shaft extending in one direction, passing through the head portion, and capable of moving back and forth in one direction to open and close the orifice.

Wherein one side of the head portion contacts the body and the second blocking portion includes a fastening unit disposed on the other side of the head portion and fastened to the shaft.

The nozzle cap includes a sealing member provided between the head part and the body and having elasticity.

An indicator is formed at a portion of the head portion corresponding to the inlet hole position.

A plurality of the inflow holes are provided. The object to be processed includes a casting that passes through a segment of the casting facility.

The body includes an air inlet communicating with the movement path, and the air inlet is disposed below the portion blocked by the cooling medium inlet and the nozzle cap of the movement path.

The present invention relates to a cleaning method for cleaning a cooling medium supply pipe for supplying a cooling medium to a nozzle, the cleaning method comprising the steps of: blocking an inlet for communicating a cooling medium movement path formed in the nozzle with the cooling medium supply pipe; A step of cutting off at least a part of the cooling medium movement path, and a process of supplying the cleaning liquid into the cooling medium supply pipe. And discharging the cleaning liquid from the inside of the cooling medium supply pipe.

The step of blocking the movement path blocks an area where the width of the movement path is narrowed.

In the process of supplying the cleaning liquid into the cooling medium supply pipe, the cleaning liquid is circulated inside the cooling medium supply pipe.

And discharging the cleaning liquid, a cooling medium movement path formed in the nozzle, and opening the inlet.

According to the embodiments of the present invention, when the cleaning operation is performed by supplying the cleaning liquid into the cooling medium supply line, the communicating portion between the nozzle and the cooling medium supply line can be blocked. Therefore, contaminated cleaning liquid can be prevented from flowing into the nozzle.

Thus, clogging of the inside of the nozzle due to foreign substances in the cleaning liquid can be prevented. Thus, it is possible to continuously and uniformly spray a certain amount of the cooling medium during the casting operation, thereby improving the quality of the cast steel. In addition, the frequency of the work of removing the foreign matter inside the nozzle is reduced, and maintenance of the equipment can be facilitated.

Further, the cleaning liquid is prevented from flowing into the nozzle, so that the cleaning liquid circulates only in the cooling medium supply pipe. Therefore, contaminated cleaning liquid can be prevented from flowing into the nozzle and flowing out to the outside through the nozzle orifice of the nozzle, and recovery of the cleaning liquid can be facilitated. Therefore, it is possible to prevent environmental pollution due to the outflow of contaminated cleaning liquid.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 shows a continuous casting installation according to an embodiment of the present invention.
2 shows a nozzle according to an embodiment of the invention.
3 is a view showing a structure of a nozzle cap according to an embodiment of the present invention.
4 illustrates operation of a nozzle according to an embodiment of the present invention.
5 is a flowchart showing a cleaning method of a cooling medium supply pipe according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be apparent to those skilled in the art that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know. To illustrate the invention in detail, the drawings may be exaggerated and the same reference numbers refer to the same elements in the figures.

Although embodiments of the present invention are illustratively described with respect to the nozzles provided in the segments of the continuous casting facility, the scope of application is not so limited and can be applied to various nozzles for jetting the cooling medium.

2 is a view illustrating a nozzle according to an embodiment of the present invention. FIG. 3 is a cross-sectional view illustrating a structure of a nozzle cap according to an embodiment of the present invention. FIG. 4 is a view showing the operation of the nozzle according to the embodiment of the present invention, and FIG. 5 is a flowchart showing a cleaning method of the cooling medium supply pipe according to the embodiment of the present invention.

A nozzle 1500 according to an embodiment of the present invention is a nozzle for spraying a cooling medium to an object to be processed. The nozzle 1500 extends in one direction and ejects a cooling medium at one end. The other end is opened. A cooling medium inlet 1520 provided in the body 1510 in a direction intersecting the extending direction of the body 1510 and communicable with the movement path, And a nozzle cap 1550 coupled to the other open end and opening / closing at least one of the inlet 1520 and the movement path. At this time, the material to be processed may be a slab passing through the segment 1000 of the casting equipment.

First, the continuous casting equipment will be described in order to understand the present invention. 1, the continuous casting facility includes a ladle 10 containing refined molten steel in a steelmaking process, a tundish 20 for receiving and temporarily storing molten steel through an injection nozzle connected to the ladle 10, a tundish And a plurality of rollers (1300, 1400) provided at a lower portion of the mold (30) for guiding the progress of cooling the unfused cast steel, wherein the segments (30) (1000).

The segment 1000 includes a main body 1100 and 1200 and a plurality of rollers 1300 and 1400 provided in the main bodies 1100 and 1200 to guide the movement of the main shaft and to press down. Between the plurality of rollers 1300 and 1400, a nozzle 1500 for spraying a cooling medium for cooling the cast steel may be disposed. The nozzle 1500 is connected to the cooling medium supply pipe 1600 and the air supply pipe 1700 to mix a plurality of fluids, for example, water and air, and then spray it to cool the slab.

However, various kinds of sludge may flow into the cooling medium supply pipe 1600 for supplying the cooling medium to the nozzle 1500, or water may be generated. When such sludge or water droplets are introduced into the nozzle 1500 together with the cooling medium, the air permeability inside the nozzle 1500 may be lowered or the inside of the nozzle 1500 may be clogged. Therefore, the main part is unevenly cooled due to the defective injection of the cooling medium, and the quality of the cast steel is deteriorated. Therefore, the cleaning liquid must be supplied into the cooling medium supply pipe 1600 to remove the water droplets or the sludge.

However, as the cleaning liquid including the sludge or the water droplet flows into the nozzle 1500 as it is, the sludge or water contained in the cleaning liquid can block the nozzle 1500. Also, the cleaning liquid including the sludge and the water may be discharged through the nozzle 1500, thereby contaminating the environment of the workplace. Therefore, the nozzle 1500 according to the embodiment of the present invention can prevent the rinsing liquid from flowing into the nozzle 1500.

2, a nozzle 1500 according to an embodiment of the present invention may include a body 1510 and a cooling medium inlet 1520 and may further include an orifice 1540 and an air inlet 1530 have. In the embodiment of the present invention, it is described that the nozzle 1500 has a structure in which the cooling medium is sprayed from the upper side to the lower side. However, the present invention is not limited thereto, The direction can be changed and applied.

The body 1510 is formed to extend in one direction, i.e., vertically. A nozzle is provided at the lower end of the body 1510 to eject a cooling medium, and an upper end of the body 1510 is opened to form an opening. In addition, a movement path through which the cooling medium can move is formed inside the body 1510.

The cooling medium inlet 1520 is provided in the body 1510 in a direction intersecting the extending direction of the body 1510 and communicates with the movement path inside the body 1510. That is, the cooling medium inlet 1520 is provided on the side of the body and is connected to the cooling medium supply pipe 1600. The cooling medium in the cooling medium supply pipe 1600 may be supplied to the movement path inside the body 1510 through the inlet 1520 and may be injected into the slip through the injection port at the lower end of the body 1510.

The air inlet 1520 is provided in the body 1510 in a direction intersecting the extending direction of the body 1510 and communicates with the movement path inside the body 1510. Accordingly, the air inlet 1530 is connected to the air supply pipe 1700 to move the air in the air supply pipe 1530 to the inside of the body 1510. In addition, an air inlet 1530 may be disposed between the injection port of the body 1510 and the cooling medium inlet 1520. Therefore, the cooling medium introduced into the movement path inside the body 1510 through the cooling medium inlet 1520 can be mixed with the air introduced into the movement path inside the body 1510 through the air inlet 1530 and sprayed.

Since the nozzle cap 1550, which will be described later, prevents the washing liquid containing the water droplets or the sludge from flowing into the body 1510, the washing liquid flows into the body 1510 and moves downward to move the air inlet 1530 To the air supply pipe (1530). That is, since the air inlet 1530 is disposed below the cooling medium supply pipe 1600, it is possible to prevent the cleaning liquid from flowing into the lower air supply pipe 1700 when the upper cooling medium inlet 1520 is blocked . Accordingly, it is possible to prevent the accumulation of water or sludge in the air inlet 1530 or the air supply pipe 1700.

An orifice 1540 is provided in the movement path inside the body 1510 and is disposed between one end of the nozzle 1550 and a top end of the body 1510, which will be described later. The perforated portion 1540a of the orifice 1540 may be formed to have a narrower width from the upper side to the lower side to have an inclined surface. Accordingly, the flow rate of the cooling medium moving from the upper side to the lower side in the movement path in the body 1510 may pass through the penetration portion 1540a of the orifice 1540. However, the structure and shape of the orifice 1540 are not limited thereto and may vary.

The nozzle cap 1550 is connected to the other open end of the body 1510, that is, the upper end of the body 1510, and includes a first blocking portion capable of blocking the cooling medium inlet 1520, And may further include a filter 1553 and a sealing member 1555.

3, the first blocking portion includes a head portion 1551 having a size larger than the diameter of the opening formed at the other end of the body 1510, and a head portion 1551 connected to the head portion 1551, And a body portion 1552 extending in one direction and having a length greater than or equal to the length from the opening to the cooling medium inlet 1520.

The head portion 1551 serves to cover the opening of the body 1510. [ Accordingly, the cooling medium introduced into the body 1510 through the cooling medium inlet 1520 can be prevented from flowing to the upper end of the body 1510. [ In addition, the head portion 1551 may be formed like a hexagon bolt head. Therefore, the head portion 1551 can be easily rotated using a tool. However, the structure and the shape of the head portion 1551 are not limited to these, and may vary.

The body portion 1552 may extend in the vertical direction and have a length greater than or equal to the length from the opening of the body 1510 to the cooling medium inlet 1520. An upper portion of the body portion 1552 is connected to a lower portion of the head portion 1551 and is installed to be insertable into the opening portion. Thus, the body portion 1552 can cover the cooling medium inlet 1520. For example, at least a portion of the body portion 1552 may be provided with a thread 1552a corresponding to the thread provided at the inner upper end of the body 1510. [ Accordingly, when the head part 1551 is tightened with a tool, the body part 1552 can be coupled to the body 1510 while rotating, and when the head part 1551 is loosened, the body part 1552 rotates to rotate the body 1510 ). ≪ / RTI >

The body portion 1552 is provided with an inlet hole 1552b in which a movement path of the cooling medium is formed and can communicate with the cooling medium inlet 1520. [ That is, the body portion 1552 is formed with a flow path of the cooling medium in the vertical direction, and the inlet hole 1552b is formed in the side surface of the body portion 1552. For example, the body portion 1552 may form an a-shaped flow path in the movement path of the body 1510. The cooling medium flowing through the cooling medium inlet 1520 passes through the inlet portion 1552b of the body portion 1552 and passes through the inside of the body portion 1552 and does not move to the upper side of the body 1510, 1510). However, the structure and shape of the body portion 1552 and the method of coupling the body 1510 to each other may be variously changed. In addition, the head portion 1551 and the body portion 1552 may be integrally formed.

The body portion 1552 can open and close the cooling medium inlet 1520. For example, when the head part 1551 is rotated as shown in FIG. 4, the body part 1552 rotates together to change the position of the inlet hole 1552b. The cooling water inlet 1520 faces the wall where the inlet hole 1552b of the body portion 1552 is not formed while the position of the inlet hole 1552b disposed opposite to the cooling water inlet 1520 is changed. The wall of the body portion 1552 may block the cooling medium inlet 1520 to block the cooling medium from flowing into the body 1510. Accordingly, when the cleaning liquid is supplied into the cooling medium supply pipe 1600, the head part 1551 is rotated to block the cooling medium inlet 1520, so that foreign substances such as water and sludge together with the cleaning liquid flow into the body 1510, It is possible to prevent clogging.

On the other hand, when the cleaning operation of the cooling medium supply pipe 1600 is completed, the head part 1551 may be rotated in the opposite direction to change the position of the inlet hole 1552b to a position facing the cooling medium inlet 1520. [ Accordingly, the cooling medium inlet 1520 is opened and the cooling medium supplied through the cooling medium supply pipe 1600 can be introduced into the body 1510 and injected toward the casting.

The filter 1553 is provided in the inlet hole 1552b and serves to filter foreign substances in the cooling medium. For example, the filter 1553 may be a mesh and may be disposed inside the body portion 1552 to cover the inlet hole 1552b. Thus, it is possible to filter out foreign matter such as sludge or sludge in the cooling medium, thereby preventing foreign matter from flowing into the inside of the body 1510.

At this time, a plurality of inflow holes 1552b may be provided. For example, three inlet holes 1552b may be provided in the body portion 1552 at intervals of 60 degrees. That is, if foreign substances are accumulated in the filter, the inlet hole 1552b may be clogged and the cooling medium may not be smoothly supplied into the body 1510. [ Accordingly, when one inlet hole is blocked, the body portion 1552 can be rotated to match another inlet hole with the cooling medium inlet 1520. For example, when the head portion 1551 is rotated by 60 degrees using a tool, the body portion 1552 connected to the head portion 1551 rotates by 60 degrees, and other inlet holes can correspond to the cooling medium inlet 1520. However, the number of the inlet holes 1552b and the positions thereof are not limited to these, and may be various.

An indicator 1551a may be formed at a portion corresponding to the position of the inlet hole 1552b of the head portion 1551. [ That is, since the inflow hole 1552b of the body portion 1552 is inserted into the body 1510, it is difficult to confirm the position from the outside. Therefore, grooves can be formed at the portions corresponding to the positions of the inlet holes 1552b of the head portion 1551 to match the grooves 1552b with the inlet 1520 of the cooling medium. However, the present invention is not limited to this, and the position of the inlet hole 1552b can be displayed by various methods such as forming a projection on the head portion 1551 or displaying a point.

The second blocking portion may include a shaft 1554 extending in one direction and passing through the head portion 1551 and being movable forward and backward in one direction to open and close the orifice 1540 and a fastening unit 1556.

The shaft 1554 extends in the vertical direction and penetrates the head portion 1551 so as to be able to move back and forth. The length of the shaft 1554 is extended beyond the length from the orifice 1540 to the head portion 1551. In addition, the lower end of the shaft 1554 may be formed into an auger shape with its width becoming narrower toward the lower side. Accordingly, when the shaft 1554 is advanced, a part of the lower end of the shaft 1554 is inserted into the orifice 1540, thereby blocking the orifice 1540 to prevent foreign matter from entering. When the shaft 1554 is retracted, the shaft 1554 is separated from the orifice 1540 so that the orifice 1540 is opened so that the cooling medium can pass through the orifice 1540. However, the structure and the shape of the shaft 1540 are not limited thereto and may vary.

The fastening unit 1556 is disposed on the other side of the head portion 1551 and fastened to the shaft 1554. [ At this time, one side of the head part 1551 is in contact with the body 1510, and the other side of the head part 1551 is in the exposed part. Further, the fastening unit 1556 may be formed in a nut shape. Thus, if the fastening unit 1556 is loosened or rolled, the shaft 1554 can move back and forth to shut off or open the orifice 1540. However, the shape of the fastening unit 1556 and the method of cutting off or opening the orifice 1540 are not limited thereto and may vary.

The sealing member 1555 is provided between the head portion 1551 and the body 1510 and may have elasticity. That is, when the head portion 1551 is rotated to change the position of the inlet hole 1552b, a gap is formed between the head portion 1551 and the body 1510, so that the cooling medium or the like can flow out. The sealing member 1555 contracts when the head part 1551 is wound and extends when the head part 1551 is loosened to cover the gap between the head part 1551 and the body 1510, And can be prevented from flowing out into the gap.

Hereinafter, a cleaning method of a cooling medium supply pipe according to an embodiment of the present invention will be described.

Referring to FIG. 5, a cleaning method of a cooling medium supply pipe according to an embodiment of the present invention is a cleaning method for cleaning a cooling medium supply pipe for supplying a cooling medium to a nozzle, A step (S100) of cutting off an inlet for communicating the medium supply pipe, and a step (S200) of cutting off at least a part of the cooling medium movement path formed in the nozzle, A process of supplying a cleaning liquid (S300), and a process of discharging the cleaning liquid from the inside of the cooling medium supply pipe (S400).

The cooling medium supply pipe 1600 for supplying the cooling medium to the nozzle 1500 may be formed in the shape of a square pipe. The cooling medium supply pipe 1600 may be connected to a plurality of cooling medium supply lines (not shown) to supply the cooling medium to the nozzle 1500. However, the structure and the shape of the cooling medium supply pipe 1600 are not limited to this, and may vary.

However, various kinds of sludge may flow into the cooling medium supply pipe 1600 for supplying the cooling medium to the nozzle 1500, or water may be generated. When such sludge or water droplets are introduced into the nozzle 1500 together with the cooling medium, the air permeability inside the nozzle 1500 may be lowered or the inside of the nozzle 1500 may be clogged. Therefore, the main part is unevenly cooled due to the defective injection of the cooling medium, and the quality of the cast steel is deteriorated. Therefore, the cleaning liquid must be supplied into the cooling medium supply pipe 1500 to remove the water droplets or the sludge.

However, as the cleaning liquid including the sludge or the water droplet flows into the nozzle 1500 as it is, the sludge or water contained in the cleaning liquid can block the nozzle 1500. Also, the cleaning liquid including the sludge and the water may be discharged through the nozzle 1500, thereby contaminating the environment of the workplace.

Therefore, it is necessary to prevent foreign substances such as sludge or water droplets from flowing into the nozzle 1500 during the cleaning operation for the cooling medium supply pipe 1600. First, the cooling medium inlet 1520 formed in the body 1510 can be blocked. For example, the position of the inlet hole 1552b for communicating the cooling medium inlet 1520 and the cooling medium moving path inside the body 1510 can be moved.

That is, when the head portion 1551 of the nozzle cap 1550 is rotated, the body portion 1552 of the nozzle cap 1550 is rotated together with the position of the inlet hole 1552b facing the cooling medium inlet 1520. Thus, the cooling medium inlet 1520 faces the wall without the inlet hole 1552b of the body portion 1552. [ Accordingly, the cooling medium inlet 1520 and the cooling medium moving path in the body 1510 are not communicated with each other, so that the washing liquid can be prevented from flowing into the cooling medium moving path in the body 1510 through the cooling medium inlet 1520.

Next, the cooling medium movement path in the body 1510 can be blocked. In particular, it is possible to block the area where the width of the movement path is narrow, for example, the orifice 1540. That is, when foreign matter enters the narrowed portion, it is easily clogged. Therefore, foreign matter should be prevented from entering the narrowed portion.

For example, the shaft 1554 of the nozzle cap 1550 can be advanced. That is, when the cooling medium is supplied into the nozzle 1500, the shaft 1554 may be spaced apart from the orifice 1540 to keep the orifice 1540 open. During the cleaning operation of the cooling medium supply pipe 1600, the shaft 1554 may be advanced to the orifice 1540 side to contact the orifice 1540 and shut off the orifice 1540. At this time, the process of shutting off the movement path in the cooling medium supply pipe 1600 and the body 1510 may be performed sequentially or simultaneously.

As described above, the inside of the nozzle 1500 is shut off in a double manner, and the cleaning liquid containing foreign substances can be prevented from flowing into the nozzle 1500. Thus, it is possible to prevent the inside of the nozzle 1500 from being clogged due to foreign substances in the cleaning liquid. Thus, it is possible to continuously and uniformly spray a certain amount of the cooling medium during the casting operation, thereby improving the quality of the cast steel. In addition, it is possible to reduce the frequency of the operation of removing the foreign substances inside the nozzle 1500, thereby facilitating the maintenance of the equipment.

At this time, the body 1510 of the nozzle 1500 may be connected to the air inlet 1530 through which air can be supplied through the movement path in the body 1510. Therefore, the cooling medium introduced into the movement path inside the body 1510 through the cooling medium inlet 1520 can be mixed with the air introduced into the movement path inside the body 1510 through the air inlet 1530 and sprayed.

In addition, the nozzle cap 1550 may block the upper area than the position where the air is supplied to the movement path in the body 1510. That is, since the air inlet 1530 is disposed below the cooling medium supply pipe 1600, it is possible to prevent the cleaning liquid from flowing into the lower air supply pipe 1700 when the upper cooling medium inlet 1520 is blocked .

The cleaning liquid can be supplied into the cooling medium supply pipe 1600 when the cooling medium inlet 1520 and the portion where the width of the movement path in the body 1510 is narrowed are blocked. For example, the cooling medium supply pipe 1600 is connected to a plurality of cooling medium supply lines, which are separated from the cooling medium supply line of the cooling medium supply pipe 1600. One of the separated portions of the cooling medium supply pipe 1600 and the cooling medium supply line may be connected to a cleaning liquid supply line (not shown) and connected to another cleaning liquid discharge line (not shown).

Then, the cleaning liquid is supplied into the cooling medium supply pipe 1600 through the cleaning liquid supply line. Thus, the cleaning liquid can move in the cooling medium supply pipe 1600 and separate foreign matter such as water or sludge present in the cooling medium supply pipe 1600 from the cooling medium supply pipe 1600. Then, the cleaning liquid moves to the cleaning liquid discharge line connected to the cooling medium supply pipe 1600 and is discharged to the outside of the cooling medium supply pipe 1600.

At this time, since the nozzle 1500 is double-blocked, the cleaning liquid circulates only in the cooling medium supply pipe 1600. Therefore, contaminated cleaning liquid can be prevented from flowing into the nozzle 1500 and flowing out to the outside through the nozzle of the nozzle 1500, and recovery of the cleaning liquid can be facilitated. Therefore, it is possible to prevent environmental pollution due to the outflow of contaminated cleaning liquid.

After discharging all of the cleaning liquid in the cooling medium supply line 1600, the cooling medium inlet 1520 that has been shut off to use the nozzle 1500 and the cooling medium movement path in the body 1510 may be opened. That is, shaft 1554 is retracted and spaced apart from orifice 1540 to open orifice 1540. The indicator 1551a formed on the head part 1551 can be positioned to face the cooling medium inlet 1520 by rotating the head part 1551. [ Accordingly, the inlet hole 1552b disposed at the position corresponding to the indicator 1551a also faces the cooling medium inlet 1520, and the cooling medium inlet 1520 is opened.

The cooling medium supplied to the cooling medium supply pipe 1600 may then flow into the body 1510 through the cooling medium inlet 1520 and be injected through the nozzle of the body 1510 through the orifice 1540. Therefore, since the inside of the cooling medium supply pipe 1600 can be cleaned and the nozzle 1500 can be prevented from being clogged with the contaminated cleaning liquid, the maintenance of the facility can be facilitated.

Although the nozzles provided in the segments of the continuous casting equipment are exemplified above, the application range is not limited thereto and can be applied to various nozzles for spraying the cooling medium.

Although the present invention has been described in detail with reference to the specific embodiments thereof, it will be apparent to those skilled in the art that various modifications and variations can be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited by the described embodiments, but should be defined by the appended claims, as well as the appended claims.

1500: nozzle 1510: body
1520: Cooling medium inlet 1530: Air inlet
1540: Orifice 1550: Nozzle cap
1551: Head part 1552: Body part
1553: filter 1554: shaft
1555: sealing member 1556: fastening unit

Claims (15)

1. A nozzle for jetting a cooling medium to an object to be processed,
A body in which a cooling medium is injected at one end, the other end is opened, and a movement path of the cooling medium is formed therein;
A cooling medium inlet provided in the body and communicable with the movement path; And
And a nozzle cap coupled to the other open end of the body and opening / closing at least one of the cooling medium inlet and the movement path,
Wherein the nozzle cap includes a first blocking portion capable of blocking the cooling medium inlet,
Wherein the first blocking portion has a head portion having a size larger than a diameter of the opening formed at the other end of the body, a head portion connected to the head portion and insertable into the opening portion, A body portion having a plurality of inlet holes that can communicate with each other, and a filter provided in the inlet hole to filter foreign substances in the cooling medium,
Wherein the body is rotatably inserted into the opening so that one inlet hole communicated with the cooling medium movement path of the plurality of inlet holes is clogged with the foreign material and the other inlet hole can be communicated with the cooling medium moving path. The method according to claim 1,
Wherein the nozzle cap further comprises a second blocking portion capable of blocking the movement path. delete delete The method of claim 2,
And an orifice disposed in a movement path inside the body and disposed between the nozzle cap and one end of the body. The method of claim 5,
Wherein the second blocking portion includes a shaft extending in one direction, passing through the head portion, and capable of moving back and forth in the one direction to open and close the orifice. The method of claim 6,
Wherein one side of the head portion is in contact with the body,
And the second blocking portion includes a fastening unit which is disposed on the other side of the head and fastened to the shaft. The method of claim 6,
Wherein the nozzle cap includes a sealing member provided between the head portion and the body and having elasticity. The method according to claim 1,
And a marker is formed at a portion corresponding to the inlet hole position of the head portion. The method according to claim 1,
Wherein the object to be processed comprises a casting that passes through a segment of a casting installation. The method according to claim 1,
Wherein the body has an air inlet communicating with the movement path,
Wherein the air inlet is disposed below the portion that is blocked by the cooling medium inlet and the nozzle cap of the movement path. A cleaning method for cleaning a cooling medium supply pipe for supplying a cooling medium to a nozzle,
Closing at least one of a cooling medium movement path formed in the nozzle and an inlet opening communicating with the cooling medium supply tube; and a step of cutting off at least a part of the cooling medium movement path formed in the nozzle.
Supplying a cleaning liquid into the cooling medium supply pipe; And
And discharging the cleaning liquid from the inside of the cooling medium supply pipe,
The nozzle includes a body having a first end and a second end, the first end being open and the second end being open, the first end being open and the second end being open, And a nozzle cap coupled to the other end and opening / closing at least one of the cooling medium inlet and the movement path,
Wherein the nozzle cap is connected to the head portion so as to be insertable into the opening portion and has a path of movement of the cooling medium formed therein and communicates with the cooling medium inlet A body portion provided with a plurality of possible inlet holes, and a filter provided in the inlet hole for filtering foreign matter in the cooling medium,
And a cooling medium supply pipe for allowing the body to be rotatably inserted into the opening so that one inlet hole communicated with the cooling medium moving path of the plurality of inlet holes is blocked by the foreign material, . The method of claim 12,
The step of intercepting the movement path includes:
Thereby blocking a region where the width of the movement path is narrowed. The method of claim 12,
In the process of supplying the cleaning liquid into the cooling medium supply pipe,
Wherein the cleaning liquid is circulated in the cooling medium supply pipe. The method of claim 12,
And a step of discharging the cleaning liquid and then opening a cooling medium movement path formed in the nozzle and the inlet port.

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