JPH11138207A - Method for draining steel sheet and device therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To dissolve irregular cooling by draining stagnant water on a steel sheet at the time of cooling the steel sheet. SOLUTION: Plural two kinds of fluid jetting nozzles 2, 3 the width of jet of which is different in the width direction of the steel sheet 22 are arranged so that the jetting direction is faced to either edge side of the steel sheet 22 and the fluid jetting nozzles 3 having the wide width of jet so as to be situated on the up-stream side of the jetting direction and, by jetting fluid on the upside of the steel sheet 22 from these plural fluid jetting nozzles 2, 3, the retaining water on the upside of the steel sheet 22 is accompanied with the jetted fluid and discharged from one edge to the other edge of the upside of the steel sheet 22.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a drainer for cooling a hot-rolled high-temperature steel sheet with water, and removing cooling water retained on the cooled steel sheet by jetting a fluid.

[0002]

2. Description of the Related Art A hot-rolled high-temperature steel sheet is cooled by a cooling device provided downstream of a finishing mill. Such a cooling device is composed of a cooling device that cools the upper surface of the steel plate and a cooling device that cools the lower surface of the steel plate, and each cooling device is composed of a plurality of banks.

[0003] As a cooling device for cooling the upper surface of the steel plate, a slit laminar system or a spray system is generally employed. When cooling the upper surface of the steel sheet by these cooling devices, the cooling water on the upper surface of the steel sheet may flow out as stagnant water in the direction of passing the steel sheet or in the opposite direction because the surface of the steel sheet is in a horizontal state.

[0004] Since such accumulated water supercools the upper surface of the steel sheet, a temperature difference occurs between the upper and lower surfaces of the steel sheet, which causes so-called C warpage. When such a C warpage occurs, an operation of correcting the C warpage by a press or a straightening machine is required, and the manufacturing cost increases.

[0005] In addition, when the accumulated water flows into another bank, the cooling stop temperature of the steel sheet varies, and the temperature distribution in the width direction of the steel sheet varies.

For these reasons, it is important to drain water so that the water remaining on the upper surface of the steel sheet does not flow into another bank, and to remove the water remaining from the upper surface of the steel sheet as soon as possible.

[0007] As a conventional draining technique for staying water on the upper surface of a high-temperature steel sheet, there is one disclosed in Japanese Patent Publication No. 59-13573. The draining method based on this technology is to inject the high-pressure fluid onto the upper surface of the steel sheet from a direction orthogonal to the steel sheet transport line so that the cooling water injected from the upper surface cooling bank to the upper surface of the steel sheet is about to be transported to the downstream side. And blow it off the line.

There is also a method in which high-pressure fluid is jetted from a nozzle disposed above the steel sheet transfer line toward the upstream side in the transfer direction to dampen the retained water.

Further, a draining roll is arranged at a position corresponding to the transport roll with the steel plate interposed therebetween, and the steel plate is sandwiched between the drain roll and the transport roll to block the retained water and drain the water. There is also a way to do it.

[0010]

However, the conventional draining method described above has the following problems. (1) Technology disclosed in Japanese Patent Publication No. 59-13573 When a large amount of stagnant water flows as in the case of cooling a thick steel plate, the collision pressure and momentum enough to overcome the flow of the stagnant water are injected. Is required for the fluid to be discharged, but because there is a certain distance between the drainer and the steel plate (there is no explanation of what the injection nozzles are and how they are arranged, the collision pressure decreases. The reason for this cannot be understood), and a decrease in the collision pressure of the fluid is inevitable.

[0011] Therefore, in order to sufficiently drain the water, the injection pressure must be increased, which increases the equipment cost.

(2) Method of injecting high-pressure fluid toward the upstream side in the transport direction Unless an injection nozzle in which the fluid to be ejected spreads in the width direction of the steel sheet is used, the flow of the stagnant water cannot be stopped over the entire width of the steel sheet. On the other hand, in the ejection nozzle in which the ejection angle of the fluid increases, the collision pressure of the fluid decreases.

Therefore, in order to increase the collision pressure of the fluid, it is necessary to increase the injection pressure or to use a large number of injection nozzles having a narrow injection angle, which increases the equipment cost,
The flow rate of the fluid used increases and the operating cost increases.

(3) Method of Using a Draining Roll If a C-warp occurs in the steel sheet with both ends facing upward or the center of the sheet facing upward during cooling, a draining roll is applied to the steel sheet. Even when pressed, the drain roll cannot be completely pressed against the upper surface of the steel plate, and a gap is formed between the steel plate and the drain roll, so that accumulated water leaks from the gap.

The present invention has been made to solve the above-mentioned problems of the prior art, and drains water remaining on the upper surface of a steel sheet without flowing out to another cooling zone. It is an object of the present invention to provide a steel plate drainer that can be removed from the upper surface of a steel plate.

[0016]

A first means for solving the above-mentioned problem is to use two types of fluid injection nozzles having different injection widths in the width direction of the steel sheet so that the injection direction is directed to one of the edge sides of the steel sheet. In this manner, a plurality of fluid ejection nozzles having a smaller ejection width are arranged so as to be located on the upstream side in the ejection direction, and the fluid is ejected from the plurality of fluid ejection nozzles to the upper surface of the steel plate, so that the stagnation of the upper surface of the steel plate. A method for draining a steel sheet, wherein water is discharged from one edge of the upper surface of the steel sheet to the other edge in association with the injected fluid.

A second means for solving the above-mentioned problem is a method of draining a steel sheet, wherein the jet directions of the two types of fluid jet nozzles are different between adjacent banks.

A third means for solving the above-mentioned problem is to use two kinds of fluid injection nozzles having different injection widths in the steel sheet width direction so that the injection direction is directed to one of the edge sides of the steel sheet, and A water draining device for a steel plate, wherein a plurality of wide fluid injection nozzles are arranged so as to be located on the upstream side in the injection direction.

A fourth means for solving the above-mentioned problem is that a draining roll is provided upstream of a position where the fluid injection nozzle is arranged, wherein the draining roll for a steel sheet according to the second invention is provided. It is.

In the above means, two types of fluid jet nozzles are used for the following reasons.

When the cross-sectional area of the collision of the jet fluid with the steel sheet is reduced, the collision pressure of the fluid per unit area is increased, and the ability to drain the retained water is increased. It is preferable to use a fluid ejection nozzle having a narrow ejection width in the width direction.

However, if all the fluid ejection nozzles are fluid ejection nozzles with a small ejection width, the collision area is small, and the ejection direction of the ejection fluid is inclined to one of the edges of the steel sheet. In the vicinity of the edge opposite to the side from which the accumulated water is discharged (the upstream side in the ejection direction), the ejected fluid hardly hits, and it becomes difficult to drain the accumulated water staying in the vicinity.

Therefore, of the fluid jet nozzles arranged on the edge of the steel plate opposite to the side from which the accumulated water is discharged,
The fluid ejection nozzle arranged at a position corresponding to the edge of the steel plate needs to be a fluid ejection nozzle having a wide ejection width instead of the above-described fluid ejection nozzle having a small ejection width. Therefore, in the above-described means, two types of fluid ejection nozzles having different ejection widths are used.

It should be noted that, for the fluid ejection nozzle having a small ejection width, a straight-type ejection nozzle is preferable in which the collision area when the fluid hits the upper surface is the same as the nozzle exit area. The jetting width may be widened to some extent from the viewpoint of the installation interval in the direction, for example, the jetting angle may be about 15 degrees or less.

Further, since the position corresponding to the edge of the steel sheet changes depending on the width of the steel sheet, the fluid injection nozzle having a wide injection width is used to completely drain the edges of the steel sheet having all the widths. At least one or more steel plates are arranged according to the amount of change in the width of the steel plate.

Further, the selection of the ejection angle of the fluid ejection nozzle having a wide ejection width may be performed in consideration of the height cylinder of the fluid ejection nozzle.

The reason why the injection direction is different between the adjacent banks is that if the injection direction is the same in all the banks, the edge of the steel plate on the side from which the retained water is discharged is supercooled. .

If a draining roll is arranged upstream of a plurality of fluid injection nozzles, a considerable amount of retained water can be drained by the draining roll even if the steel plate is warped in C. Since the amount of stagnant water flowing toward the side where the fluid ejection nozzle is arranged is reduced, the collision pressure and momentum of the relatively ejected fluid become large enough to overcome the stagnant water flow, and Water can be drained efficiently.

The draining fluid ejected from the fluid ejecting nozzle may be compressed air or a mixed fluid of water and compressed air in addition to ordinary water.

[0030]

Embodiments of the present invention will be described below with reference to the accompanying drawings.

FIG. 1 is a front view of a steel plate drainer according to a first embodiment of the present invention. This steel plate drainer 1
Are arranged linearly above the steel sheet 22 conveyed by the conveying roll 21 and along the width direction of the steel sheet 22 and have a plurality of jets whose injection direction is inclined toward one edge 22a of the steel sheet 22 (in FIG. 1, (3) narrow fluid ejection nozzles (hereinafter referred to as narrow ejection nozzles) 2 and a plurality of narrow ejection nozzles 2 arranged on the most upstream side in the ejection direction, that is, on the other edge 22b side of the steel plate 22. A plurality of (two in FIG. 1) fluid ejection nozzles (hereinafter, referred to as wide ejection nozzles) 3 having an ejection direction inclined toward one edge 22a of the steel plate 22 in the same manner as the narrow ejection nozzle 2; It is composed of

When the retained water remaining on the upper surface of the steel plate 22 is drained by the drainer 1, the fluid is directed from the plurality of narrow jet nozzles 2 toward the upper surface of the steel plate 22 to cut off the fluid when the fluid is jetted. The fluid is injected such that the area and the cross-sectional area of the fluid when the fluid collides with the steel plate 22 are not changed as much as possible.

From the wide jet nozzle 3, the fluid is directed toward the upper surface of the steel plate 22 so that the cross-sectional area at the time of jetting the fluid is
The fluid is jetted such that the cross-sectional area of the fluid when colliding with the steel plate 22 is increased.

By injecting the fluid in this manner, the fluid having a large collision pressure and a large momentum collides with the flow of the stagnant water, and the stagnant water is applied to the steel plate 2.
2 accompanying the flow of the fluid after colliding with the upper surface of the steel plate 2
2 is drained to one edge 22a side.

If only the narrow jet nozzle 2 is used, the fluid jetting angle in the vicinity of the other edge 22b of the steel plate 22 is inclined toward the one edge 22a of the steel plate 22, so that the fluid does not hit and the drainage is performed. Although it may not be performed, the draining device 1 for the steel plate has the wide jet nozzle 3 disposed on the other edge 22b side of the steel plate 22, so that the draining is completely performed.

The width of the steel plate 22 is, as shown in FIG.
Since the width W changes from the minimum width W _min to the maximum width W _max , the wide jet nozzle 3 cannot be covered by only the outermost one, that is, the fluid may not hit the other edge 22 b of the steel plate 22. Is as shown in FIG.
Place two or more.

FIG. 2 is a front view of a steel plate drainer according to a second embodiment of the present invention. This draining device 4 has a draining roll 5 arranged upstream of the steel plate draining device 1 of the first embodiment in correspondence with a transport roll 23 of a steel plate 22. Draining can be performed by being sandwiched between the transporting roll 23 and the draining roll 5.

In the case of this water draining device 4, even if the steel plate 22 is warped in C, a considerable amount of retained water can be drained by the water draining roll 5, and the fluid injection nozzles 2 and 3 can be drained. Since the amount of stagnant water flowing to the downstream bank where the water is flowing is reduced, the collision pressure and momentum of the ejected fluid are large enough to overcome the stagnant water flow, and the stagnant water is drained efficiently. can do.

In the case where water is used as the draining fluid, as shown in the plan view of FIG. Is increased, and the one edge 22a of the steel plate 22 tends to be supercooled. Therefore, when a plurality of draining devices are arranged along the transport direction of the steel plate 22, the direction of the flow 6 in which the stagnant water and the draining water are mixed may be alternately changed.

FIG. 3 shows an example of the steel plate draining device according to the second embodiment in which the draining rolls 5 are disposed. However, in the steel plate draining device according to the first embodiment, the accumulated water and the drainage water are also used. And the direction of the flow 6 in which is mixed is preferably changed alternately.

[0041]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A slit laminator comprising ten banks, and a draining roll is arranged between each bank in correspondence with a transport roll (a cooling water amount of 2000 l / m in each bank)
^The cooling was performed by passing a steel plate having a temperature of 800 ° C., a width of 4.5 m and a width of 2 m into a cooling device for ² min with the draining roll lowered.

The draining device of the present invention (narrow jet nozzle 3) disposed at the entrance of the first bank (upstream of the draining roll) and at the exit of the tenth bank (downstream of the draining roll).
Pressure, 6 kg / c
m ² of water was sprayed at a rate of 80 l / min per nozzle.

When the temperature distribution in the width direction of the steel sheet cooled in this manner was examined, the temperature difference in the sheet width direction was ± 10 ° C. for both the 4.5 m and 2 m width steel sheets, No significant difference in hardness distribution was observed, and no cooling unevenness due to cooling occurred.

In the case of the comparative example cooled under the same conditions and not using the draining device of the present invention, the temperature difference in the width direction of the steel sheets of 4.5 m and 2 m was ±±.
It was 100 ° C., and the hardness distribution in the width direction examined at the same time also showed high hardness portions at both edges.

From this, it can be seen that the use of the water draining device of the present invention can reduce cooling unevenness and eliminate deformation of the steel sheet and variation in the material.

[0046]

According to the present invention, when cooling a steel sheet, the steel sheet can be cooled uniformly in the width direction of the steel sheet, so that variations in the material and deformation of the steel sheet are reduced, and the product yield of the steel sheet is improved. .

Further, since the work for correcting the deformation of the steel plate is reduced, the manufacturing cost can be reduced.

[Brief description of the drawings]

FIG. 1 is a front view of a steel plate drainer according to a first embodiment of the present invention.

FIG. 2 is a front view of a steel plate drainer according to a second embodiment of the present invention.

FIG. 3 is a plan view of a steel plate drainer according to a second embodiment of the present invention, in which the direction of drainage is alternately changed.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Drainer 2 Narrow jetting nozzle 3 Wide jetting nozzle 4 Drainer 5 Draining roll 6 Flow in which stagnant water and draining water are mixed

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor Naoto Hirata 1-2-1, Marunouchi, Chiyoda-ku, Tokyo Nihon Kokan Co., Ltd. (72) Inventor Yoshitaka Inoue 1-2-1, Marunouchi, Chiyoda-ku, Tokyo Sun (72) Inventor Yoneaki Fujita 1-1-2 Marunouchi, Chiyoda-ku, Tokyo Nihon Kokan Co., Ltd.

Claims (4)

[Claims] 1. A fluid jet nozzle having two jets having different jet widths in the steel sheet width direction, wherein the jet direction is directed to one edge side of the steel sheet, and the fluid jet nozzle having a wider jet width is jet direction. Arrange more than one so as to be located on the upstream side,
By injecting fluid from the plurality of fluid injection nozzles onto the upper surface of the steel plate, the accumulated water on the upper surface of the steel plate is discharged from one edge of the upper surface of the steel plate to the other edge accompanying the injected fluid. Draining method. 2. The method for draining a steel sheet according to claim 1, wherein the injection directions of the two types of fluid injection nozzles are different between adjacent banks. 3. The two types of fluid injection nozzles having different injection widths in the steel sheet width direction such that the injection direction is directed to one of the edge sides of the steel sheet, and the fluid injection nozzle having the smaller injection width is upstream of the injection direction. A water draining device for a steel plate, wherein a plurality of the drainage devices are arranged so as to be positioned on a side. 4. The steel plate draining device according to claim 3, wherein a draining roll is provided upstream of a position where the fluid injection nozzle is arranged.