KR101291561B1 - Steam blocking apparatus - Google Patents

Abstract

The present invention relates to a water vapor blocking apparatus, comprising: a rolling unit for rolling a material, a conveying roller part disposed at the rear of the rolling part, for conveying a material sent out from the rolling part, and a conveying roller part disposed above the conveying roller part. A descaler section for spraying the washing water toward the back, a width measuring section disposed behind the descaler section, and a width measuring section for measuring the width of the material, and a descaler section and the width measuring section, and the water vapor generated by evaporation of the wash water is wide. It characterized in that it comprises a shield for sucking the air on the side of the width measuring unit to block the flow into the measuring unit to spray toward the feed roller.
According to the present invention, since the washing water injected from the descaler unit is prevented from entering the width measuring unit by the water vapor generated by evaporation, it is possible to accurately measure the width of the material.

Description

Steam Blocker {STEAM BLOCKING APPARATUS}

The present invention relates to a water vapor blocking device, and more particularly to a water vapor blocking device that can improve the width measurement accuracy of the material by blocking the water vapor generated by evaporation of the washing water injected from the descaler to the width measuring unit. It is about.

Typical steelmaking consists of a steelmaking process to produce molten iron, a steelmaking process to remove impurities from molten iron, a casting process to solidify the liquid iron, and a rolling process to make iron into steel or wire.

The rolling process refers to a process in which intermediate materials such as slabs and blooms produced in the playing process are passed between several rotating rollers to be stretched or thinned by applying a continuous force, and are roughly divided into hot rolling and cold rolling.

The technical structure described above is a background technique for assisting the understanding of the present invention, and does not mean the prior art widely known in the technical field to which the present invention belongs.

An object of the present invention is to provide a water vapor blocking device that can improve the width measurement accuracy of the material by blocking the water vapor generated by evaporation of the washing water injected from the descaler to the width measuring unit.

Water vapor blocking device according to an aspect of the present invention: a rolling unit for rolling a material; A conveying roller part disposed at the rear of the rolling part to convey the material sent from the rolling part; A descaler part disposed above the feed roller part and configured to spray washing water toward the feed roller part; A width measuring unit disposed behind the descaler and measuring a width of the material; And a shield disposed between the descaler unit and the width measuring unit, and sucking air on the width measuring unit side to inject air toward the conveying roller unit to prevent water vapor generated by evaporation of the washing water from flowing into the width measuring unit. Contains wealth.

Preferably, the shielding portion, the body portion fixed to the external device; And it is rotatably coupled to the lower end of the body portion, and includes an air curtain portion for injecting the air on the side of the width measuring unit and sprayed toward the feed roller.

More preferably, the air curtain portion, the inlet is formed on the side facing the width measuring portion, the discharge port is formed on the side facing the feed roller portion; A fan rotatably installed in the case; And a fan motor disposed inside the case and rotating the fan.

Preferably, the lifting unit coupled with the shield for lifting the shield; And a control unit for controlling the operation of the lifting unit.

More preferably, the lifting unit, the drive motor fixed to the external device; A rotary gear connected to the drive motor and rotated by driving of the drive motor; A rack gear meshed with the rotary gear and lifted by the rotation of the rotary gear; And a connecting plate having one side coupled to the rack gear and the other side coupled to the shield.

More preferably, further comprising a displacement sensor installed on the connecting plate, the distance sensor for sensing the distance to the material, the control unit to operate the drive motor based on the distance to the material measured by the displacement sensor To control.

More preferably, the shielding portion, the body portion fixed to the connecting plate; And it is rotatably coupled to the lower end of the body portion, and includes an air curtain portion for injecting the air on the side of the width measuring unit and sprayed toward the feed roller.

More preferably, the air curtain portion, the inlet is formed on the side facing the width measuring portion, the discharge port is formed on the side facing the feed roller portion; A fan rotatably installed in the case; And a fan motor disposed inside the case and rotating the fan.

Water vapor blocking device according to another aspect of the present invention: a rolling unit for rolling a material; A conveying roller part disposed at the rear of the rolling part to convey the material sent from the rolling part; A descaler part disposed above the feed roller part and configured to spray washing water toward the feed roller part; A width measuring unit disposed behind the descaler and measuring a width of the material; A shielding part disposed between the descaler and the width measuring part to block the water vapor generated by evaporation of the washing water from entering the width measuring part; A lift unit coupled with the shield to lift the shield; And a control unit for controlling the operation of the lifting unit.

Preferably, the lifting unit, the drive motor fixed to the external device; A rotary gear connected to the drive motor and rotated by driving of the drive motor; A rack gear meshed with the rotary gear and lifted by the rotation of the rotary gear; And a connecting plate having one side coupled to the rack gear and the other side coupled to the shield.

More preferably, further comprising a displacement sensor installed on the connecting plate, the distance sensor for sensing the distance to the material, the control unit to operate the drive motor based on the distance to the material measured by the displacement sensor To control.

More preferably, the shielding portion, the body portion fixed to the connecting plate; And a fluid injection part rotatably coupled to the lower end of the body part, the fluid injection part injecting a fluid toward the feed roller part, wherein the fluid injection part is connected to an external source and connected to supply a fluid; Branch pipe branched from the connecting pipe; And a nozzle provided in the branch pipe to inject a fluid toward the feed roller.

According to the present invention, since the washing water injected from the descaler unit is prevented from entering the width measuring unit by the water vapor generated by evaporation, it is possible to accurately measure the width of the material.

In addition, according to the present invention, since the rotating part is rotatably coupled with respect to the body part, the impact during the collision between the material and the rotating part can be reduced.

In addition, according to the present invention, the height of the shield can be adjusted to prevent the collision between the material and the shield, as well as to place the shield close to the material to minimize the movement of water vapor through the gap between the shield and the material. Can be.

1 is a perspective view showing a water vapor blocking device according to an embodiment of the present invention.
Figure 2 is a perspective view showing a shield of the water vapor blocking device according to an embodiment of the present invention.
Figure 3 is a perspective view of the air curtain portion of the water vapor blocking device according to an embodiment of the present invention.
Figure 4 is a side view showing a water vapor blocking device according to an embodiment of the present invention.
5 is a view showing the operating state of the water vapor blocking device according to an embodiment of the present invention when the front end portion of the material passes the shield.
6 is a view showing an operating state of the water vapor blocking device according to an embodiment of the present invention when the central portion of the material passes the shield.
7 is a view showing the operating state of the water vapor blocking device according to an embodiment of the present invention when the end of the material passes the shield.
8 is a perspective view showing a state in which the air curtain portion is rotated to the right in the water vapor blocking device according to an embodiment of the present invention.
9 is a perspective view showing a state in which the air curtain portion is rotated to the left in the water vapor blocking device according to an embodiment of the present invention.
10 is a block diagram showing the control flow of the water vapor blocking device according to an embodiment of the present invention.
11 is a perspective view showing a water vapor blocking apparatus according to another embodiment of the present invention.
12 is a perspective view showing a shield of the water vapor blocking device according to another embodiment of the present invention.
13 is a cross-sectional view showing a fluid injection part of the water vapor blocking device according to another embodiment of the present invention.
14 is a bottom view showing a fluid injection part of the water vapor blocking device according to another embodiment of the present invention.
15 is a side view showing a water vapor blocking device according to another embodiment of the present invention.
16 is a view showing an operating state of the water vapor blocking device according to another embodiment of the present invention when the front end portion of the material passes the shield.
17 is a view showing the operating state of the water vapor blocking device according to another embodiment of the present invention when the central portion of the material passes the shield.
18 is a view showing an operating state of the water vapor blocking device according to another embodiment of the present invention when the tail end of the material passes the shield.
19 is a perspective view showing a state in which the fluid injection unit is rotated to the right in the water vapor blocking device according to another embodiment of the present invention.
20 is a perspective view showing a state in which the fluid injection unit is rotated to the left in the water vapor blocking device according to another embodiment of the present invention.
21 is a block diagram showing a control flow of the water vapor blocking device according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the water vapor blocking device according to the present invention. For convenience of explanation, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation.

Further, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

1 is a perspective view showing a water vapor blocking device according to an embodiment of the present invention, Figure 2 is a perspective view showing a shield of the water vapor blocking device according to an embodiment of the present invention, Figure 3 is an embodiment of the present invention It is a perspective view showing the air curtain portion of the water vapor blocking device according to. Figure 4 is a side view showing a water vapor blocking device according to an embodiment of the present invention, Figure 5 is a view showing the operating state of the water vapor blocking device according to an embodiment of the present invention when the front end portion of the material passes the shield, 6 is a view showing the operating state of the water vapor blocking device according to an embodiment of the present invention when the central portion of the material passes through the shield, Figure 7 is an embodiment of the present invention when the end of the material passes through the shield 8 is a perspective view showing a state in which the air curtain portion is rotated to the right in the water vapor blocking device according to an embodiment of the present invention, Figure 9 is an embodiment of the present invention 10 is a perspective view showing a state in which the air curtain portion is rotated to the left in the water vapor blocking device according to the present invention, and FIG. Illustrating a control flow block diagram.

11 is a perspective view showing a water vapor blocking device according to another embodiment of the present invention, Figure 12 is a perspective view showing a shield of the water vapor blocking device according to another embodiment of the present invention, Figure 13 is another embodiment of the present invention FIG. 14 is a cross-sectional view illustrating a fluid injection part of the water vapor shutoff device according to an embodiment of the present invention. 15 is a side view showing a water vapor blocking device according to another embodiment of the present invention, Figure 16 is a view showing the operating state of the water vapor blocking device according to another embodiment of the present invention when the front end portion of the material passes the shield, 17 is a view showing the operating state of the water vapor blocking device according to another embodiment of the present invention when the central portion of the material passes through the shield, Figure 18 is another embodiment of the present invention when the end of the material passes through the shield Figure showing the operating state of the water vapor blocking device according to. 19 is a perspective view showing a state in which the fluid injection unit rotates to the right in the water vapor blocking device according to another embodiment of the present invention, Figure 20 is a fluid injection unit is rotated to the left in the water vapor blocking device according to another embodiment of the present invention Figure 21 is a perspective view showing a state, Figure 21 is a block diagram showing the control flow of the water vapor blocking device according to another embodiment of the present invention.

1 to 3, the water vapor blocking device according to an embodiment of the present invention is a rolling unit 10, the transfer roller unit 20, the descaler 30, the width measuring unit 40, the shielding unit 50, the control unit 80 is included.

The rolling section 10 rolls the work S to a target thickness and width so as to facilitate finish rolling in the finish rolling process. The rolled portion 10 includes an upper work roll (not shown) arranged on the upper side and a lower work roll (not shown) arranged on the lower side.

The material S is rolled by the upper work roll and the lower work roll while being transferred between the upper work roll and the lower work roll. The material S rolled and delivered by the rolling section 10 is conveyed to a post-process by the conveying roller section 20. [

The conveying roller portion 20 is disposed behind the rolled portion 10. The conveying roller unit 20 includes a conveying roller (not shown) for conveying the work S to a post-process and a roller support (not shown) for rotatably supporting both ends of the conveying roller.

The descaler portion 30 is disposed above the feed roller portion 20. The descaler unit 30 removes the scale formed on the surface of the material S transported by the feed roller unit 20 by spraying high-pressure washing water toward the feed roller unit 20.

The descaler 30 is disposed in front of the width measuring unit 40 (see FIG. 1). Therefore, since the scale formed on the surface of the material S before passing through the width measuring part 40 is removed by the descaler 30, the measurement of the width measuring part 40 by the scale surrounding the material S is performed. It prevents the deterioration of accuracy.

The width measuring unit 40 is disposed above the feed roller unit 20. Width measuring unit 40 measures the width of the material (S) to be conveyed by the feed roller unit 20. Width measuring unit 40 may be made of a laser displacement sensor.

The laser displacement sensor is disposed above the feed roller portion 20 forming the feed path of the material S to irradiate the laser toward the feed roller portion 20. When the material S passes through the point where the laser is irradiated, the laser reflected from the surface of the material S is received by the laser displacement sensor again, and the laser displacement sensor measures the width of the material S by using the laser displacement sensor.

The width measuring unit 40 transmits the width S 40 to the controller 80 when the width of the material S is measured. The control unit then controls the rolling process based on the width information of the received material (S).

The shield 50 is disposed above the feed roller 20. The shielding part 50 is disposed between the descaler 30 and the width measuring part 40 to block the introduction of water vapor into the width measuring part 40, which may reduce the measurement accuracy of the width measuring part 40. do.

The washing water sprayed from the descaler 30 is evaporated after being in contact with the high temperature material S to phase change into water vapor, and the shield 50 prevents the water vapor from entering the width measuring unit 40. .

The shielding part 50 includes a body part 51 and an air curtain part 52.

Body portion 51 is fixed while being coupled to the external device (F) or the lifting unit (60). Wherein the external device (F) may be a rolling frame or a roller table forming a frame of the rolling section 10, any other configuration if the body 51 can be disposed above the feed roller section 20 It may be. When the body 51 is fixed to the external device F, the shield 50 is not moved up and down, and when the body 51 is coupled to the lift 60, the shield 50 is moved up and down. Can be.

The air curtain portion 52 is hingedly coupled to the body portion 51. The upper end of the air curtain part 52 (see FIG. 2) is hinged to the lower end of the body part 51 by the hinge part 53. As a result, the air curtain part 52 may be freely rotated with respect to the body part 51.

When the material S is bounced upward in the process of being conveyed in the forward direction or in the reverse direction, the air curtain part 52 is rotatably coupled with respect to the body part 51, so that when the material S is collided, Shock can be reduced.

8 illustrates a state in which the air curtain portion 52 is rotated to the right by collision with the raw material S during the transfer of the raw material S in the forward direction, and FIG. 9 illustrates the transfer of the raw material S in the reverse direction. The state in which the air curtain part 52 rotates to the left side by the collision with the raw material S is shown. As such, when colliding with the material S, the air curtain part 52 is rotated in the advancing direction of the material S, thereby minimizing the impact due to the collision.

The air curtain part 52 injects air toward the material S transported by the feed roller part 20, that is, the feed roller part 20, thereby closing the gap between the air curtain part 52 and the material S. Through this, the water vapor is blocked from moving to the width measuring unit 40. As described above, since the water injected from the air curtain unit 52 can prevent water vapor from entering the width measuring unit 40, the width of the material S can be accurately measured through the width measuring unit 40. do.

The air curtain part 52 sucks air on the width measuring part 40 side and injects toward the feed roller part 20. This eliminates the need for a separate air supply from the outside, simplifying the installation and reducing the cost.

The air curtain part 52 includes a case 55, a fan 56, and a fan motor 57. The case 55 is hinged to the body 51 and forms an outer shape of the air curtain 52. The case 55 has a suction port 55a formed on the side facing the width measuring part 40, and a discharge port 55b formed on the side facing the feed roller 20.

The fan 56 is rotatably installed inside the case 55, the fan motor 57 is disposed inside the case 55, and generates power to rotate the fan 56. When the fan motor 57 is driven by the instruction of the controller 80, the fan 56 is rotated. When the fan 56 is rotated, the air on the width measuring part 40 side is sucked into the case 55 through the suction port 55a, and is discharged toward the feed roller part 20 through the discharge port 55b.

Since an air curtain is formed between the air curtain portion 52 and the material S by the air discharged through the discharge port 55b, through the gap between the air curtain portion 52 and the material S. Water vapor is blocked to move to the width measuring unit (40).

4 to 7, 10, the water vapor blocking device according to an embodiment of the present invention may further comprise a lifting unit 60, the displacement sensor 70.

The lifting unit 60 is combined with the shield 50 to lift the shield 50. The lifting unit 60 includes a drive motor 61, a rotary gear 62, a rack gear 63, and a connecting plate 64. In the case of the water vapor blocking device additionally provided with the lifting unit 60, the body 51 is coupled to the connecting plate 64, not the external device (F).

The drive motor 61 generates power and is fixed to the external device F. Here, the external device F may be a rolling frame or a roller table constituting the frame of the rolling unit 10, any other configuration can be fixed to the drive motor 61.

The rotary gear 62 is connected to the drive motor 61 and rotates by receiving power from the drive motor 61 when the drive motor 61 is driven. The rack gear 63 meshes with the rotary gear 62 and is raised or lowered by the rotation of the rotary gear 62. One side of the connecting plate 64 is coupled to the rack gear 63, and the other side of the connecting plate 64 is coupled to the body 51 of the shield 50. Therefore, when the rack gear 63 is raised or lowered by the operation of the drive motor 61, the shield 50 is raised or lowered in the same direction as the rack gear 63. That is, the rising or falling of the shielding unit 50 may be controlled by the operation control of the driving motor 61 through the control unit 80.

Displacement sensor 70 is installed on the connecting plate 64, and detects the distance to the material (S). The displacement sensor 70 is disposed closer to the rolled portion 10 than the shield 50 so that the material S passes through the lower portion of the displacement sensor 70 earlier than the lower portion of the shield 50.

The displacement sensor 70 transmits the distance from the measured material S to the controller 80, and the controller 80 controls the operation of the driving motor 61 based on this. In order to prevent the movement of water vapor through the gap between the shield 50 and the material S, the gap between the shield 50 and the material S should be minimized along with the operation of the air curtain part 52. In this case, when the shield 50 is located close to the material S, the shield 50 and the material S may collide with each other due to the upward of the material S, and thus the shield 50 may be damaged. . In order to prevent this, the displacement sensor 70 notifies the controller 80 when the distance from the material S is smaller than the reference value based on the set reference value to induce the rise of the shield 50 through the driving motor 61. 5 and 7. In addition, the displacement sensor 70 notifies the controller 80 when the distance from the material S is greater than the set reference value to induce the lowering of the shield 50 through the driving motor 61 (FIG. 6). At this time, the shield 50 is raised while the rotation gear 62 is rotated in one direction by the one-way rotation of the driving motor 61, and the rack gear 63 engaged with the rotation gear 62 moves upward. That is, the shield 50 is raised by the upward movement of the rack gear 63. On the contrary, the lowering of the shield 50 is performed while the rotary gear 62 is rotated in the other direction by the rotation of the drive motor 61 in the other direction, and the rack gear 63 engaged with the rotary gear 62 moves downward. . That is, the shield 50 descends by the lower movement of the rack gear 63.

11 to 15, the water vapor blocking device according to another embodiment of the present invention is a rolling unit 110, a transfer roller unit 120, a descaler 130, a width measuring unit 140, a shielding unit It comprises 150, the lifting unit 160, the displacement sensor 170, the controller 180.

The rolling unit 110 rolls the material S to a target thickness and width such that the material S is easily finished in the finishing rolling process. The rolling unit 110 includes an upper work roll (not shown) disposed above and a lower work roll (not shown) disposed below.

The material S is rolled by the upper work roll and the lower work roll while being transferred between the upper work roll and the lower work roll. The raw material S rolled and sent from the rolling unit 110 is transferred to the post process by the transfer roller unit 120.

The conveying roller part 120 is disposed behind the rolling part 110. The conveying roller part 120 includes a conveying roller (not shown) for conveying the raw material S to a later process, and a roller support (not shown) for rotatably supporting both ends of the conveying roller.

The descaler 130 is disposed above the feed roller 120. The descaler 130 removes the scale formed on the surface of the material S transported by the feed roller 120 by spraying high-pressure washing water toward the feed roller 120.

The descaler 130 is disposed in front of the width measuring unit 140 (see FIG. 11). Therefore, since the scale formed on the surface of the material S before passing through the width measuring part 140 is removed by the descaler 130, the width measuring part 140 is measured by the scale surrounding the material S. It prevents the deterioration of accuracy.

The width measuring part 140 is disposed above the feed roller part 120. Width measuring unit 140 measures the width of the material (S) to be conveyed by the feed roller 120. Width measuring unit 140 may be made of a laser displacement sensor.

The laser displacement sensor is disposed above the feed roller part 120 forming the feed path of the material S to irradiate the laser toward the feed roller part 120. When the material S passes through the point where the laser is irradiated, the laser reflected from the surface of the material S is received by the laser displacement sensor again, and the laser displacement sensor measures the width of the material S by using the laser displacement sensor.

The width measuring unit 140 transmits the measured width of the material S to the controller 180. The control unit then controls the rolling process based on the width information of the received material (S).

The shielding part 150 is disposed above the feed roller part 120. The shielding part 150 is disposed between the descaler 130 and the width measuring part 140 to block the introduction of water vapor into the width measuring part 140, which may reduce the measurement accuracy of the width measuring part 140. do.

The washing water sprayed from the descaler 130 is evaporated after being in contact with the high temperature material S to phase change into water vapor, and the shield 150 prevents water vapor from flowing into the width measuring unit 140. .

The shielding part 150 includes a body part 151 and a fluid injection part 152. The body 151 is coupled to the lifting unit 160. The fluid injection part 152 is hingedly coupled to the body part 151. The upper end portion (see FIG. 12) of the fluid injection portion 152 is hinged to the lower end portion of the body portion 151 by the hinge portion 153. As a result, the fluid injection part 152 may be freely rotated with respect to the body part 151.

When the material (S) is bounced upward in the process of transporting in the forward direction or in the reverse direction, the fluid injection part 152 is rotatably coupled to the body portion 151, so when the collision with the material (S) Shock can be reduced.

FIG. 19 illustrates a state in which the fluid injection part 152 is rotated to the right by collision with the material S when the material S is transferred in the forward direction, and FIG. 20 is conveyed in the reverse direction of the material S. The state in which the fluid injection part 152 rotates to the left by the collision with the raw material S is shown. As such, when the material S collides with the material S, the fluid injection part 152 is rotated in the advancing direction of the material S, thereby minimizing an impact due to the collision.

The fluid injection part 152 injects a high pressure fluid toward the feed roller part 120, that is, the material S conveyed by the feed roller part 120, thereby providing the fluid injection part 152 and the feed roller part 120. The water vapor is prevented from moving to the width measuring unit 140 through the gap therebetween. In this embodiment the fluid is air. As such, since the water injected from the fluid spraying unit 152 may block water vapor from entering the width measuring unit 140, the width of the material S may be accurately measured through the width measuring unit 140. do.

The fluid injection part 152 includes a connection pipe 155, a branch pipe 156, a nozzle 157, and a housing 158. The connecting pipe 155 communicates with an external source and receives fluid from the external source to guide the branch pipe 156 to the branch pipe 156.

A plurality of branch pipes 156 are formed by branching from the connecting pipe 155, and a plurality of branch pipes 156 are arranged in a line in the width direction of the material S. Therefore, the path in which water vapor flows into the width measurement unit 140 is blocked in a wide range.

The nozzle 157 is provided at one end of the branch pipe 156 to inject a high-pressure fluid toward the feed roller 120, specifically, the material S conveyed by the feed roller 120. Therefore, an air curtain is formed between the fluid injection unit 152 and the material S to block water vapor from entering the width measurement unit 140.

The housing 158 covers the connecting pipe 155, the branch pipe 156, and the nozzle 157, and the connecting pipe 155, the branch pipe 156, and the nozzle 157 collide with the material S. It prevents breakage at the time and suppresses deterioration damage in high temperature environment.

The lifting unit 160 is combined with the shield 150 to lift the shield 150. The lifting unit 160 includes a driving motor 161, a rotary gear 162, a rack gear 163, and a connecting plate 164.

The drive motor 161 generates power and is fixed to the external device (F). Here, the external device F may be a rolling frame or a roller table constituting the frame of the rolling unit 110, any other configuration can be fixed to the drive motor 161.

The rotary gear 162 is connected to the drive motor 161 and is rotated by receiving power from the drive motor 161 when the drive motor 161 is driven. The rack gear 163 meshes with the rotary gear 162 and is raised or lowered by the rotation of the rotary gear 162. One side of the connecting plate 164 is coupled to the rack gear 163, the other side is coupled to the body portion 151 of the shielding part 150. Therefore, when the rack gear 163 is raised or lowered by the operation of the drive motor 161, the shield 150 is raised or lowered in the same direction as the rack gear 163. That is, the rising or falling of the shielding unit 150 may be controlled by controlling the operation of the driving motor 161 through the controller 180.

15 to 18 and 21, the displacement sensor 170 is installed on the connecting plate 164, and detects the distance to the material (S). The displacement sensor 170 is disposed closer to the rolling unit 110 than the shield 150 so that the material S passes through the lower portion of the displacement sensor 170 earlier than the lower portion of the shield 150.

The displacement sensor 170 transmits the measured distance from the material S to the controller 180, and the controller 180 controls the operation of the driving motor 161 based on this. In order to prevent the movement of water vapor through the gap between the shield 150 and the material S, the gap between the shield 150 and the material S should be minimized. In this case, when the shielding part 150 is located close to the material S, the shielding part 150 may collide with the material S due to the upward of the material S, and the shielding part 150 may be damaged. . In order to prevent this, the displacement sensor 170 notifies the controller 180 when the distance from the material S is smaller than the reference value based on the set reference value and induces the rising of the shield 150 through the driving motor 161. 16 and 18. In addition, the displacement sensor 170 notifies the controller 180 when the distance from the material S is greater than the set reference value to induce the lowering of the shield 150 through the driving motor 161 (FIG. 17). At this time, the shield 150 is raised by rotating the rotational gear 162 in one direction by the one-way rotation of the drive motor 161, the rack gear 163 meshed with the rotary gear 162 is moved upward. That is, the shield 150 is raised by the upward movement of the rack gear 163. On the contrary, the lowering of the shielding part 150 is performed while the rotary gear 162 is rotated in the other direction by the rotation of the driving motor 161 in the other direction, and the rack gear 163 engaged with the rotary gear 162 moves downward. . That is, the shield 150 is lowered by the downward movement of the rack gear 163.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. I will understand.

Accordingly, the true scope of the present invention should be determined by the following claims.

10: rolling section 20: conveying roller section
30 descaler 40 width measurement unit
50: shield 51: body
52: air curtain portion 60: lifting portion
70: displacement sensor 80: control unit

Claims (12)

A rolling section for rolling the material;
A conveying roller part disposed at the rear of the rolling part to convey the material sent from the rolling part;
A descaler part disposed above the feed roller part and configured to spray washing water toward the feed roller part;
A width measuring unit disposed behind the descaler and measuring a width of the material; And
A shielding part disposed between the descaler and the width measuring part and sucking air on the width measuring part side to inject air toward the conveying roller part so as to block the water vapor generated by evaporation of the washing water from entering the width measuring part. Including,
The shielding portion, the body portion fixed to the external device; And
The water vapor blocking device is rotatably coupled to the lower end of the body portion, the air curtain portion for sucking the air on the side of the width measuring portion and spraying toward the feed roller.
delete The method of claim 1,
The air curtain unit, the case in which the inlet is formed on the side facing the width measuring unit, the outlet is formed on the side facing the transfer roller;
A fan rotatably installed in the case; And
It is disposed inside the case, the water vapor blocking device comprising a fan motor for rotating the fan.
The method of claim 1,
A lift unit coupled with the shield to lift the shield; And
And a control unit for controlling the operation of the lifting unit.
5. The method of claim 4,
The lifting unit, the drive motor fixed to the external device;
A rotary gear connected to the drive motor and rotated by driving of the drive motor;
A rack gear meshed with the rotary gear and lifted by the rotation of the rotary gear; And
One side is coupled to the rack gear, the other side of the water vapor blocking device comprising a connection plate coupled to the shield.
The method of claim 5,
It is installed on the connecting plate, and further comprises a displacement sensor for sensing the distance to the material,
The control unit is a water vapor blocking device, characterized in that for controlling the operation of the drive motor based on the distance to the material measured by the displacement sensor.
The method according to claim 6,
The shielding portion, the body portion fixed to the connecting plate; And
The water vapor blocking device is rotatably coupled to the lower end of the body portion, the air curtain portion for sucking the air on the side of the width measuring portion and spraying toward the feed roller.
The method of claim 7, wherein
The air curtain unit, the case in which the inlet is formed on the side facing the width measuring unit, the outlet is formed on the side facing the transfer roller;
A fan rotatably installed in the case; And
It is disposed inside the case, the water vapor blocking device comprising a fan motor for rotating the fan.
A rolling section for rolling the material;
A conveying roller part disposed at the rear of the rolling part to convey the material sent from the rolling part;
A descaler part disposed above the feed roller part and configured to spray washing water toward the feed roller part;
A width measuring unit disposed behind the descaler and measuring a width of the material;
A shielding part disposed between the descaler and the width measuring part to block the water vapor generated by evaporation of the washing water from entering the width measuring part;
A lift unit coupled with the shield to lift the shield; And
It includes a control unit for controlling the operation of the lifting unit,
The lifting unit, the drive motor fixed to the external device;
A rotary gear connected to the drive motor and rotated by driving of the drive motor;
A rack gear meshed with the rotary gear and lifted by the rotation of the rotary gear; And
One side is coupled to the rack gear, the other side of the water vapor blocking device comprising a connection plate coupled to the shield.
delete 10. The method of claim 9,
It is installed on the connecting plate, and further comprises a displacement sensor for sensing the distance to the material,
The control unit is a water vapor blocking device, characterized in that for controlling the operation of the drive motor based on the distance to the material measured by the displacement sensor.
12. The method of claim 11,
The shielding portion, the body portion fixed to the connecting plate; And
It is rotatably coupled to the lower end of the body portion, and includes a fluid injection unit for injecting a fluid toward the feed roller,
The fluid injection unit may be connected to an external source and connected to supply fluid;
Branch pipe branched from the connecting pipe; And
And a nozzle provided in the branch pipe, the nozzle injecting fluid toward the feed roller.

Images