KR101353641B1 - Apparatus for slowly cooling wire coil - Google Patents

Abstract

The wire coil slow cooling apparatus according to the present invention is provided on the edge portion side of the wire coil in the slow cooling cover and provided with one or more air cooling type cooling means for increasing the cooling capacity for the edge portion of the wire rod coil, The central and edge portions of the can be cooled slowly evenly.
That is, openings are formed in both side surfaces adjacent to the edge of the wire rod coil in the slow cooling cover, and when the window is opened, outside air is transferred to the edge portion of the wire rod coil through the opening. The edge portion may be eccentrically cooled in an air-cooled manner as it is brought into contact with the edge portion while being biased, i. Accordingly, the temperature can be made the same as the center portion by intensive cooling of the edge portion having a higher stacking density than the center portion and having a relatively higher temperature.
In addition, by controlling the opening degree of the window while controlling the temperature measurement of the center portion and the edge portion of the wire rod coil measured by the radiation thermometer with data from the controller, the temperature of the edge portion of the wire rod coil can be maintained the same as the center portion. .
As a result, according to the uniform cooling according to the present invention it is possible to improve the quality of the wire rod product by preventing material deviation due to uneven cooling of the wire coil.

Description

Wire rod coil cooling device {Apparatus for slowly cooling wire coil}

The present invention relates to a wire coil slow cooling apparatus, wherein the wire coil slow cooling apparatus is configured to uniformly cool the edge portion of the wire coil.

1 is a view showing a conventional wire coil slow cooling apparatus, Figure 2 is a view showing the lamination density in the width direction of the wire coil to be loaded and transported.

Referring to the drawings, in general, the wire coil process is to roll the steel strip to the wire coil (4) by the rolling mill (1) and to cool by the water cooling device (2), and then to roll the rolled wire coil (4) to the laying head (3) ) Is rolled up and placed in a ring shape on the transfer roll 5 and air-cooled while transferring it.

At this time, the wire coil 4 to be air-cooled is quenched or slow cooled according to the required mechanical properties, in the case of the wire coil (4) that requires strength from the nozzle (6) installed under the transfer roll (5), such as wind and steam Is sprayed on the surface of the wire coil 4 to be transported to quench, and in the case of the wire coil 4 requiring high elongation, the slow cooling cover 10 covering the upper portion of the transfer roll 5 as shown in FIG. 1. Using a method of slow cooling the wire coil (4) using.

FIG. 2 is a diagram showing the lamination density in the width direction (that is, in the width direction of the feed roll 5) of the wire rod 4 loaded and conveyed on the feed roll 5, wherein the wire coil 4 has a ring shape. The lamination density at the center portion of the wire rod coil 4 in the width direction is lower.

Therefore, the edge portion of the wire rod 4 having high lamination density has a small surface area to mass and thus has low heat loss, and the central portion of the wire rod 4 having low lamination density has a large surface area to mass and thus a relatively large annual loss. Between the edge portion and the center portion of the wire coil 4 is subjected to different cooling history and accordingly the microstructure is changed to cause a difference in mechanical properties.

In addition, the difference in the mechanical properties of the wire rod (4) due to such cooling deviation is slow cooling work due to the slow moving speed of the feed roll (5), the long cooling time and the large difference in lamination density at the center and edge of the wire coil (4) This occurs seriously at the time, which causes quality deviations by positional differences in the final product of the wire rod (4), and deteriorates the quality, making it difficult for end users to set the reference point of work when machining the wire coil (4). There is a problem of lowering the reliability.

The present invention has been made to solve the above problems, to provide a wire coil slow cooling apparatus configured to increase the cooling capacity for the edge portion of the wire coil to uniformly cool the edge portion of the wire coil. Has its purpose.

In order to achieve the above object, the wire coil slow cooling apparatus according to a preferred embodiment of the present invention is arranged on the rear end of the laying head and a slow cooling cover surrounding the transfer path with a transfer roll for transferring the wire coil; And air-cooled cooling means configured to be provided at one or more edge portions of the wire rod coil in the slow cooling cover to increase the cooling capability for the edge portion of the wire rod coil.

At this time, the cooling means, openings formed on both side portions of the slow cooling cover; And a window portion having a window for opening and closing the opening.

The cooling means may further include: a radiation thermometer installed at the slow cooling cover to measure temperatures of the wire coil center and the edge, respectively; And a control unit electrically connected to the radiation thermometer and the window unit to control the degree of opening of the window, while feedback-controlling the temperature measurement measured by the radiation thermometer with data.

Here, the window portion, the window corresponding to the opening formed on both side portions of the slow cooling cover; And a driving member for providing a driving force to automatically open and close the window.

At this time, the drive member as an embodiment, the servo motor having a screw shaft installed along the edge of the opening; And a bracket fixed to one side of the window and fastened to the screw shaft to move along the screw shaft as the screw shaft rotates.

In another embodiment, the window is hinged to the edge of the opening, the drive member, the cylinder is provided in the width direction on the lower surface of the slow cooling cover; A rotating link having one end pivoted with the window and the other end pivoted with the end of the piston rod; And a fixed link connecting the link and the window.

The wire coil slow cooling apparatus according to the present invention is provided on the edge portion side of the wire coil in the slow cooling cover and provided with one or more air cooling type cooling means for increasing the cooling capacity for the edge portion of the wire rod coil, Has the effect of uniformly slow cooling the center and the edge of the.

That is, openings are formed at both side surfaces adjacent to the wire coil edge portion in the slow cooling cover, and when the window is opened, outside air flows through the opening to the edge portion of the wire coil, and thus the outside air is particularly biased toward the edge portion of the wire coil. That is, the edge portion may be concentrated-cooled in an air-cooled manner as it contacts the edge portion while being concentrated and flowing. Accordingly, the temperature can be made the same as the center portion by intensive cooling of the edge portion having a higher stacking density than the center portion and having a relatively higher temperature.

At this time, by controlling the opening degree of the window while controlling the temperature measurement of the center and the edge of the wire rod coil measured by the radiation thermometer with data from the controller, the temperature of the edge of the wire coil 4 is maintained to be the same as the center portion. can do.

As a result, according to the uniform cooling according to the present invention by preventing the material deviation due to the uneven cooling of the wire coil has the advantage of improving the quality of the wire coil product.

Furthermore, by controlling the cooling rate of the edge of the wire coil, it is possible to control the decarburization generation, and in the future, the high-strength spring steel structure and the decarburization control can be made to contribute to material improvement and development of new steel grades.

1 is a view showing a conventional wire coil slow cooling apparatus.
2 is a diagram showing the lamination density in the width direction of the wire rod to be loaded and transported.
3 is a view showing a wire coil slow cooling apparatus according to a preferred embodiment of the present invention.
Figure 4 is a view showing that the window is opened and closed by the drive member according to an embodiment in the wire coil slow cooling apparatus of FIG.
5 is a view showing that the window is opened and closed by a drive member according to another embodiment in the wire coil slow cooling apparatus of FIG.

Hereinafter, the present invention will be described in detail with reference to the drawings.

Figure 3 is a view showing a wire coil slow cooling apparatus according to a preferred embodiment of the present invention, Figure 4 is a view showing a window opening and closing by the drive member according to an embodiment in the wire coil slow cooling apparatus of Figure 3, 5 is a view showing that the window is opened and closed by the drive member according to another embodiment in the wire coil slow cooling apparatus of FIG.

Referring to the drawings, the present invention includes a slow cooling cover 100 disposed at the rear end of the laying head (3 in FIG. 1), and cooling means installed in the slow cooling cover 100.

The slow cooling cover 100 is installed on the rear side of the laying head, it is configured to surround the transfer path with a transfer roll for transferring the wire coil (4).

That is, the slow cooling cover 100 is disposed on both sides of the transfer roll in the vertical direction along the conveying path, respectively, the upper side portion 101 and the upper side portion 103 to connect the upper side of the side portion 103 on both sides, On the lower side, a lower surface portion 102 that connects the lower portion of the side portion 103 is disposed.

The slow cooling cover 100 formed as described above is configured to block the wire rod coil 4 transferred on the feed roll from the outside air at a predetermined interval except for the front and rear sides, and has an upper surface portion 101 having the above-described shape. ) And the lower surface portion 102, and the side portion 103 is not limited by the present invention as a specific example and may take any shape that is configured to be gradually cooled while the wire coil 4 is transported on the transfer roll.

In addition, the cooling means is provided on the edge portion side of the wire coil 4 in the slow cooling cover 100 is provided at least one.

The cooling means is an air cooling type cooling means for increasing the cooling ability of the wire coil (4) to the edge portion, and serves to reduce the temperature deviation of the center portion and the edge portion of the wire coil (4).

Specifically, the cooling means has a window portion 220 having an opening 103a formed in both side portions 103 of the slow cooling cover 100 and a window 220 for opening and closing the opening 103a.

At this time, the window 220 is a window 220 installed in the opening 103a formed on both side portions 103 of the slow cooling cover 100 and the window so that the opening 103a is automatically opened and closed by the window 220. A driving member 240 for driving the 220 is provided.

In this case, the window 220 is formed to have a size corresponding to the opening 103a. When the window 220 is positioned in the opening 103a, the window 220 is sealed and the opening 103a is separated from the opening 103a. It plays an open role.

In this way, openings 103a are formed at both side portions 103 of the slow cooling cover 100 adjacent to the edge of the wire rod coil 4 so that the outside air is opened through the openings 103a when the window 220 is opened. The edge part of the coil 4 flows to the edge part, and thus the edge part can be unidirectionally cooled in an air-cooled manner as the outside air comes into contact with the edge part while being particularly biased, that is, concentrated and flowing.

Accordingly, the temperature can be made the same as the center portion by intensive cooling of the edge portion having a higher stacking density than the center portion and having a relatively higher temperature.

4 is a view showing that the window is opened and closed by the drive member 240 according to an embodiment in the wire coil slow cooling apparatus of FIG.

Referring to the drawings, the driving member 240 is, as an example, a servomotor 242 having a screw shaft 242a installed along the edge of the opening 103a, and a bracket fastened to the screw shaft 242a. 243.

The servo motor 242 has a screw shaft 242a as a motor shaft, the screw shaft 242a is formed with a screw thread on the outer peripheral surface.

The servo motor 242 is electrically connected to the control unit C, and the drive control by the control unit (C).

In addition, the bracket 243 is fixed to one side of the window 220, preferably fixed to the lower end of the window 220. The bracket 243 is fastened to the screw shaft 242a to move along the screw shaft 242a as the screw shaft 242a rotates.

This is a fastening portion of the bracket 243 to the screw shaft 242a, and a screw thread corresponding to the screw line of the outer circumferential surface of the screw shaft 242a is formed on the inner surface thereof, whereby the bracket 243 engaged with the screw shaft 242a rotates. The screw shaft 242a is moved along.

As the bracket 243 moves along the screw shaft 242a, the window 220 fixed to the bracket 243 is moved to open or close the opening 103a of the slow cooling cover 100.

5 is a view showing that the window is opened and closed by the drive member 240 according to another embodiment in the wire coil slow cooling apparatus of FIG.

Referring to FIG. 5, in another embodiment, the driving member 240 includes a cylinder 246 provided in a width direction on a lower surface portion 102 outside the slow cooling cover 100, and a piston 246a of the cylinder 246. And a rotating link 247 connected to the rotating link 247 and a fixed link 248 connected to the rotating link 247 and fixed to the window 220.

The cylinder 246 is configured in the lower surface portion 102 of the slow cooling cover 100 so that the piston 246a in the arrangement structure can be extended and contracted in the width direction of the slow cooling cover 100.

The cylinder 246 is electrically connected to the control unit C as the electron cylinder 246, and is driven and controlled by the control unit C.

In addition, one end of the rotary link 247 is pivotally engaged with the end of the piston 246a and the other end is pivotally fastened with the fixed link 248. In addition, the fixed link 248 is pivotally connected to the other end of the rotary link 247 and fixed to the window 220.

In addition, the window 220 may be hinged to the edge of the opening 103a, and may be rotatable about the hinge to be opened and closed.

Accordingly, the rotary link 247 may push the fixed link 248 toward the opening 103a side or pull downward while the piston 246a extends and contracts and rotates at the end of the piston 246a.

That is, the rotating link 247 is connected to one end of the fixed link 248 fixed to the window 220, the cylinder 246 is operated to move to the extension side when the piston 246a is extended, one end of the fixed link Are rotated along (248).

The fixed link 248 is fixed to the window 220, where the window 220 is hinged to the lower edge of the opening 103a, so that the window 220 can only rotate the fixed link ( 248, the rotating link 247 is pulled up in sequence.

In addition, when the piston 246a of the cylinder 246 contracts, the fixed link 248 is pulled while one end rotates while the back link 247 is retracted.

This is because the fixed link 248 and the rotation link 247 fixed to the window 220 is allowed only rotational movement is connected.

On the other hand, the cooling means is electrically connected to the radiation thermometer (260) installed in the slow cooling cover 100, the radiation thermometer (260) and the window 220 to measure the temperature of the central portion and the edge portion of the wire coil (4), respectively The control unit C may be further provided.

The radiation thermometer 260 is a thermometer used to measure the temperature of an object from a distance, and measures the temperature with a voltmeter by converting radiation from the object into an electrical signal.

The radiation thermometer 260 measures the temperature of the center portion and the edge portion of the wire rod coil 4, respectively. In order to measure the temperature of the center portion of the wire rod coil 4, the upper surface portion 101 inside the slow cooling cover 100 is preferable. In order to measure the temperature of the edge portion of the wire rod coil 4, it is preferably installed on the side portion 103 inside the slow cooling cover 100.

At this time, the radiation thermometer 260 installed on the side portion 103 may be fixed to be inclined to be more preferably facing the edge portion in order to measure the temperature of the edge portion of the wire coil (4).

In addition, the control unit (C) serves to control the opening degree of the window 220, while controlling the feedback of the temperature measurement measured by the radiation thermometer 260 with data.

At this time, feedback control refers to a control which performs a corrective operation so that the values of the control amounts are compared with the target values by returning the output signals to the input signals and matching them.

The present invention is configured as described above, the air-cooling type is provided on the edge portion side of the wire rod coil 4 in the slow cooling cover 100 to increase the cooling capacity for the edge portion of the wire rod coil (4) By providing the cooling means, the central portion and the edge portion of the wire rod coil 4 can be uniformly slow cooled.

That is, openings 103a are formed at both side portions 103 adjacent to the edges of the wire rod coil 4 in the slow cooling cover 100, so that the outside air is opened through the openings 103a when the window 220 is opened. It is conveyed to the edge portion side of (4), and thus the edge portion can be unidirectionally cooled in an air-cooled manner as the outside air comes into contact with the edge portion while being particularly biased, ie, biased and conveyed.

Accordingly, the temperature can be made the same as the center portion by intensive cooling of the edge portion having a higher stacking density than the center portion and having a relatively higher temperature.

In addition, at this time, by controlling the opening degree of the window 220 while controlling the temperature measurement values of the center portion and the edge portion of the wire rod coil 4 measured by the radiation thermometer 260 with data from the controller C, the wire rod coil 4 is controlled. The temperature of the edge portion of the can be kept the same as the center portion.

As a result, according to the uniform cooling according to the present invention it is possible to improve the quality of the wire coil (4) product by preventing the material deviation due to uneven cooling of the wire coil (4).

Further, by controlling the cooling rate of the edge portion of the wire coil (4) it can also control the decarburization generation, and in the future high-strength spring steel structure, by enabling the control of decarburization can contribute to material improvement and new steel grade development.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

100: slow cooling cover 101: upper surface
102: lower surface portion 103: side portion
103a: opening 220: window
240, 240 ': drive member 242: servo motor
242a: screw shaft 243: bracket
246: cylinder 246a: piston
247: rotating link 248: fixed link
260: radiation thermometer C: control unit

Claims (6)

A slow cooling cover disposed at the rear end of the laying head and surrounding the transfer path together with a transfer roll for transferring the wire rod; And air-cooled cooling means configured to be provided at one or more edge portions of the wire rod coil in the slow cooling cover to increase the cooling capability of the wire rod coil edge portion.
The cooling means may include openings formed at both side portions of the slow cooling cover; And a window having a window for opening and closing the opening.
The window unit, the window provided in the opening formed in both side portions of the slow cooling cover; And a driving member for driving the window to automatically open and close the opening by the window.
The window is hinged to the edge of the opening, the drive member, the cylinder having a piston that extends and contracts in the width direction of the slow cooling cover, the cylinder is provided on the lower surface outside the slow cooling cover; A rotating link having one end pivoted with the end of the piston; And a fixed link pivotally connected to the other end of the pivot link and fixed to connect the window.
delete The method of claim 1,
The cooling means may include: a radiation thermometer installed in the slow cooling cover to measure the temperature of the center portion and the edge portion of the wire rod coil, respectively; And
A control unit electrically connected to the radiation thermometer and the window unit for controlling the opening degree of the window while feedback-controlling the temperature measurement measured by the radiation thermometer as data;
Wire coil slow cooling apparatus characterized in that it further comprises.
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