KR101325353B1 - Apparatus for removing remaining water - Google Patents

Abstract

Residual water removal device according to the present invention, the frame is installed in the lower portion of the material to proceed; And inclination means installed on the frame to incline the material so as to block the cooling water sprayed or dropped from staying on the upper surface of the material.
As described above, the present invention is provided with an inclined feed roll to be inclined at a predetermined angle to advance the raw material, so that the coolant sprayed or dropped on the upper surface of the raw material is discharged in a direction inclined downward from the upper surface of the raw material by its own weight. Therefore, it is possible to efficiently remove the remaining water without a separate removal device.
Accordingly, the surface of the material can be uniformly cooled, which has the advantage of increasing the quality of the product.

Description

Apparatus for removing remaining water}

The present invention relates to a retentive water removing apparatus for removing a residing water remaining on an upper surface of a raw material after cooling water is sprayed or dropped onto an ongoing material.

FIG. 1 is a schematic view showing a general thick plate rolling process, and FIG. 2 is a view showing that the rolled material remains after cooling in the cooling zone of FIG. 1.

Referring to the drawings, the slab manufactured by the continuous casting process is heated in the heating furnace 2 to the target temperature according to the steel grade, and the rolling material 1 passing through the heating furnace 2 is roughness rolling machine ( Through rolling steps such as roughing mill (RM) and finishing mill (FM) machine 3, the material is rolled to a certain thickness, for example, the thickness of the final product, to produce a rolled plate 1a such as a thick plate. .

Next, the rolled sheet material 1a, such as a thick plate, rolled to a predetermined plate thickness by finish rolling is subjected to the cooling facility 7 for accelerated cooling for heat treatment such as grain refinement or control of the transformation structure.

Then, in order to increase the quality of the rolled product (thick plate product), the calibration step through the calibrator 4, that is, the flattening step, and finally the cooling table 5 is completed as a product.

In the above-mentioned cooling installation 7, it is possible to adjust the cooling water injection section according to the thickness and type of the rolled sheet material 1a.

For example, in the case of the comparatively thin rolled sheet material 1a, since the cooling amount is relatively small, the cooling water injection section in the cooling installation 7 becomes relatively small, and in the case of the relatively thick rolled sheet material 1a, the cooling amount Since it is relatively large, the cooling water injection section in the cooling installation 7 becomes relatively large.

In the related art, the setting and adjustment of such cooling water injection section have been set and adjusted from the entrance side of the rolled sheet material 1a of the cooling installation 7, that is, on the basis of the entrance side.

That is, according to the thickness or the kind of the rolled sheet material 1a, the cooling water injection section in the cooling installation 7 became large toward the exit direction based on the rolled sheet material 1a entrance side of the cooling installation 7. As shown in FIG.

When the rolled sheet material 1a passes through the cooling water injection section of the cooling facility 7 set and adjusted as described above, a part of the injected coolant stays in the rolled sheet material 1a to generate the residual water 9.

Unlike the cooling water sprayed to exist relatively uniformly on the rolled sheet material 1a, the retained water 9 is non-uniformly present in the rolled sheet material 1a, whereby the rolled sheet material 1a is locally cooled and thus the rolled sheet material ( The surface of 1a) becomes uneven. That is, the surface of the rolled sheet material 1a is deformed.

In order to correct this, the above-described calibrator 4 is placed next to the cooling installation 7 to uniformly correct the surface of the non-uniform rolled sheet material 1a.

However, when the number of staying water 9 is excessively present on the surface of the rolled sheet material 1a, since the deformation of the surface of the rolled sheet material 1a is severely performed, there is a problem that the flatness of the surface of the rolled sheet material 1a is not good. .

Therefore, in order to correct the flatness of the surface of the rolled sheet material 1a, the correction factor for correcting the flatness of the surface of the rolled sheet material 1a is increased by using the calibrator 4 positioned next to the cooling installation 7. There was this.

As described above, the cooling rate of the steel sheet is maximized when the low-temperature cooling water is in direct contact with the high-temperature steel sheet. When the cooling water is continuously supplied, the residual water 9 accumulates on the surface of the steel sheet so that the low-temperature cooling water does not directly contact the plate surface. The cooling rate will fall.

In addition, the phenomenon that the steel sheet is continuously cooled by the remaining water 9 remaining even when the cooling water supply is turned off occurs.

3 and 4 is a view showing a conventional water removal device.

Referring to Figure 3, our conventional residual water removal apparatus. When the high temperature steel plate 11 is advanced by the feed roll 12, when the cooling water 17 is supplied from the cooling header 13 above the steel plate 11, the cooling water 17 dropped to the steel plate 11 is applied to the surface of the steel plate 11. After stacking, the steel plate 11 moves together in the direction of travel. A high-pressure vertical spray 14 is disposed in the middle of the cooling header 13 so that the retention water 18 moves along the steel plate 11. Block doing

Referring to FIG. 4, there is shown a conventional water retaining device (JP2005-189575), and the restraint roll 15 is installed on the upper portion of the feed roll 12 to improve the straightness of the steel sheet 11 and stay at the same time. The water 18 is prevented from flowing in the steel plate 11 advancing direction.

However, the vertical spray 14 or the restraining roll 15 has an effect of blocking the retention water 18 flowing along the steel sheet 11 from flowing in the moving direction of the steel sheet 11, but the vertical spray 14 and the vertical spray ( 14) or in the area between the restraint roll 15 and the restraint roll 15, the retained water 18 is trapped so that the remaining water 18 cannot be completely removed except at the end of the cooling zone. Then, the falling coolant does not come into direct contact with the plate, and further cooling unintended by the retention water 18 occurs when the cooling headers 13 need to be turned on and off in a cooling pattern in the cooling zone. As a result, the cooling pattern control is also disadvantageous.

The present invention was devised to solve the above problems, and is configured to allow the material to be inclined to be discharged in the inclined direction by its own weight, so that the remaining water can be efficiently removed without a separate removal device. The purpose is to provide a removal device.

Retaining water removal apparatus according to a preferred embodiment of the present invention in order to achieve the above object, the frame is installed in the lower portion of the material; And inclination means installed on the frame to incline the material so as to block the cooling water sprayed or dropped from staying on the upper surface of the material.

At this time, the inclined means, it is rotatable so that the material entering and settled to the upper, the inclined conveying roll is formed so that the upper contact surface in contact with the material is inclined;

In addition, the inclined means, it is preferable to further include a vertical support roll rotatably disposed between the inclined feed roll and the inclined feed roll on one side inclined downward to prevent the material from sliding down.

On the other hand, according to another preferred embodiment of the present invention, the inclined feed roll is preferably tapered in an upwardly inclined direction.

The inclined means as described above, may further include a guide member disposed between the horizontal conveying roll and the inclined conveying roll to prevent the material to advance.

Residual water removing apparatus according to the present invention, by providing a slant feed roll to proceed while inclining the material in progress at a predetermined angle, the cooling water sprayed or dropped on the upper surface of the material in the direction inclined downward from the upper surface of the material by its own weight As it is to be discharged, it has the effect of efficiently removing the remaining water without a separate removal device.

Accordingly, the surface of the material can be uniformly cooled, which has the advantage of increasing the quality of the product.

1 is a schematic view showing a general thick plate rolling process.
2 is a view showing that the retained water remains after cooling the rolling material in the cooling zone of FIG.
3 and 4 is a view showing a conventional water removal device.
5 is a front view showing that the residual water is removed by the residual water removal device according to a preferred embodiment of the present invention.
FIG. 6 is a perspective view illustrating an arrangement of the retentive water removing device of FIG. 5.
FIG. 7 is a side view illustrating the residual water removing device of FIG. 6.
8 is a front view showing that the retained water is removed by the retained water removing device according to another preferred embodiment of the present invention.

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

FIG. 5 is a front view illustrating the removal of retention water by the retention water removal device according to the preferred embodiment of the present invention. FIG. 6 is a perspective view illustrating an arrangement of the retention water removal device of FIG. 5, and FIG. It is a side view which shows a residual water removal apparatus.

Referring to the drawings, the present invention includes a frame 40 installed in the lower portion of the material 20 is in progress, and the inclination means provided in the frame 40.

At this time, the frame 40 is fixedly disposed on the lower portion of the material 20 is in progress, is installed so as to transfer the material 20 while the inclined feed roll 60 of the inclined means to be described later stably disposed, The specific structure is not limited by the present invention.

In addition, the inclined means is installed on the frame 40, and serves to incline the material 20 to block the coolant 17 to be sprayed or dropped to stay on the upper surface of the material (20).

Specifically, the inclined means is provided with an inclined feed roll 60 is formed so that the material 20 to be transported along the upper surface.

Here, the inclined feed roll 60 forms a rotatable structure so that the material 20 to enter and settle upwards is transferred.

In addition, the inclined feed roll 60 may be configured to be driven to rotate by a driving means (not shown) such as a motor, or the high-temperature material 20 having a long length on the feed roll disposed at the front and rear ends. Since it can be configured to be guided while simply rotating without a driving force therebetween, which is not limited by the present invention.

The inclined feed roll 60 as described above is formed such that the upper contact surface in contact with the raw material 20 is inclined at an appropriate angle θ.

To this end, the inclined feed roll 60 is installed on the frame 40 so that both sides are fixed at different heights, thereby forming an overall inclined arrangement structure.

That is, the inclined feed roll 60 is fixed at a position where one end is higher or lower than the other end, and is formed to be inclined downward in one direction when viewed from the direction in which the raw material 20 proceeds.

Accordingly, when the coolant 17 is sprayed or dropped from the upper side of the raw material 20 which proceeds on the inclined feed roll 60, it flows to one side along the inclined upper surface without remaining on the upper surface of the raw material 20. The material 20 will fall outward.

By the way, here, by the inclined feed roll 60 inclined in the process of the material 20, it can be lowered to one side inclined downward.

That is, the raw material 20 can slide downward to the side inclined downward by the inclination of the inclined feed roll 60.

The inclined means may further include a vertical support roll 70 rotatably disposed between the inclined feed roll 60 and the inclined feed roll 60 of one side inclined downward to prevent such a point.

Of course, at this time, the vertical support roll 70 is also disposed between the inclined feed roll 60 and the inclined feed roll 60 and only serves as a locking jaw that causes one side of the material 20 to be slid downward to one side. However, the specific installation structure is not limited.

As an example, the vertical support roll 70 is vertically installed on the frame 40, but is mounted to be rotatable, and slides downward toward the inclined side while guiding the rotating material 20 to continue to advance in the traveling direction. It acts to block it.

On the other hand, Figure 8 is a front view showing that the residual water is removed by the residual water removal apparatus according to another embodiment of the present invention.

According to another preferred embodiment of the present invention, as shown in FIG. 8, the inclined feed roll 60 'may be tapered in an upwardly inclined direction.

That is, the inclined feed roll 60 ′ may have a roll shape in which the diameter thereof decreases in an upwardly inclined direction. In other words, the inclined feed roll 60 'has a roll formation in which the diameter thereof becomes larger in the downwardly inclined direction.

As described above, the inclined feed roll 60 'having a tapered shape uses the difference in the tangential velocity of the material due to the change in the rotation radius, whereby the material 20 is transferred on the inclined feed roll 60. This prevents you from going down the slope.

Specifically, when the tapered inclined feed roll 60 'is rotated about its rotation axis, the smaller diameter side rotates relatively slowly and the larger diameter side rotates relatively quickly.

Since the rotation speed is different according to the diameter in this way, the portion of the material 20 that proceeds at a relatively fast rotational part proceeds at a high speed, and the portion of the material 20 that proceeds at a relatively slow rotational part. Will slow down.

Accordingly, the portion of the material 20 that proceeds at a high speed has a tendency to rotate around the portion of the material 20 that proceeds at a slow speed.

As a result, the movement of the workpiece 20 to descend to the inclined side and the above-described movement to rotate are combined, so that the workpiece 20 proceeds in the original direction.

That is, the raw material 20 can be advanced in the original traveling direction without being slid in the downwardly inclined direction by the inclined feed roll 60 'tapered in the upwardly inclined direction.

Of course, the inclined feed roll 60 'having the tapered shape at this time is preferably inclined at an appropriate angle θ so that the upper contact surface is in contact with the material so that the material does not descend to the downwardly inclined side in view of the tangential velocity received by the material. Do.

On the other hand, the inclined means, as shown in Figures 6 and 7, the guide member disposed to advance by preventing the raw material 20 between the horizontal feed roll 8 and the inclined feed roll 60 80 may be further provided.

The guide member 80 is disposed at a step between the horizontal feed roll 8 and the inclined feed roll 60 for transferring the raw material 20, so that the raw material 20 is smoothly guided even in a transfer path having a large height difference. do.

Specifically, the guide member 80 is disposed inclined between the horizontal feed roll 8 and the inclined feed roll 60, thereby forming a structure of connecting the horizontal feed roll 8 and the inclined feed roll (60).

Accordingly, the upper surface of the raw material 20 is prevented by lowering the raw material 20 traveling from the horizontal feed roll 8 to the inclined feed roll 60 or the inclined feed roll 60 to the horizontal feed roll 8. The front end portion is not lowered to the bottom of the horizontal feed roll (8) or inclined feed roll (60) out of the course.

Such a guide member 80 is more preferably configured to have an elastic force, thereby preventing damage to the material 20 while reducing the impact when the material 20 is in contact, and can also reduce the wear of the guide member 80. have.

As one example, the guide member 80 may be composed of an upper prevention paper portion 81 and a support bracket 82 in which an elastic member 83 is provided to provide an elastic force to the upper prevention paper portion 81.

As a result, the present invention configured as described above, by providing the inclined feed rolls 60, 60 'to proceed while tilting the material 20 to be advanced at a predetermined angle, it is sprayed or dropped on the upper surface of the material 20 As the cooling water 17 is discharged in the downwardly inclined direction from the upper surface of the raw material 20 by its own weight, the remaining water can be efficiently removed without a separate removing device.

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.

8: horizontal feed roll 17: cooling water
20: material 40: frame
60, 60 ': inclined feed roll 70: vertical support roll
80: guide member 81: upper prevention branch
82: support bracket

Claims (5)

A frame 40 installed on the lower portion of the material 20 in progress; And inclination means installed on the frame 40 to incline the material 20 to prevent the cooling water 17 sprayed or dropped from staying on the upper surface of the material 20.
The inclined means, the inclined feed roll rotatable in the upwardly inclined direction is formed to be inclined to the upper side is in contact with the raw material 20 is rotated to be transported, the seat 20 is inclined upwardly; And a guide member (80) disposed between the horizontal feed roll (8) and the inclined feed roll to protrude the material (20).
Residual water removal device characterized in that it comprises a.
delete The method of claim 1,
The inclination means,
A vertical support roll 70 disposed between the inclined feed roll and the inclined feed roll on one side inclined downward to prevent the material 20 from sliding downward;
Residual water removal device characterized in that it further comprises.
delete delete

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