JP4725718B2 - Steel strip cooling device - Google Patents

Description

  The present invention relates to a steel strip cooling device used in a continuous hot dip galvanizing facility, and more particularly to improvement of sheet passing properties during cooling of a steel strip after plating.

Conventionally, in continuous hot dip galvanizing equipment, the steel strip is heated and soaked to a predetermined temperature, then cooled to a predetermined temperature and immersed in a hot dip galvanizing bath to form a hot dip galvanized film on the surface. Alternatively, the hot dip galvanized film is alloyed in an alloying furnace and then cooled by a cooling device.
In continuous hot dip galvanizing equipment, a cooling device using gas or water is used as a steel strip cooling device after plating. In these cooling devices 10, a pair of box-type cooling boxes 11 are usually provided alone or in a plurality of pairs with a steel strip S as a body to be cooled interposed therebetween as shown in FIG. The steel strip S is cooled by spraying gas or water on the front and back surfaces of the steel strip through a number of nozzles 12. In such a cooling device, the gas that collides with the steel strip generally has a structure that rebounds and flows out from the side opening in the width direction of the steel strip while forming a gas layer along the cooling box. .

  In recent years, due to the strong demand for improving the productivity of hot-dip galvanized steel sheets, there has been a strong demand for improving the cooling ability of steel strips in continuous hot-dip galvanizing equipment. In response to such a demand, it is conceivable to first improve the cooling capacity using a conventional cooling device. However, in order to increase the cooling capacity, it is necessary to blow a large amount of gas onto the steel strip at a high speed. Since the installation location of the presser roll is limited, there is a problem that the flapping of the steel strip cannot be sufficiently suppressed.

For such a problem, for example, in Patent Document 1, a plurality of protruding nozzles are provided on the surfaces of a pair of cooling boxes facing a steel strip that runs in the vertical direction, and along the running direction of the steel strip, A steel strip cooling device has been proposed in which a plurality of baffle plates are erected at predetermined intervals in the width direction of the steel strip. According to the apparatus described in Patent Document 1, the cooled gas flow can be discharged also in the vertical direction of the steel strip. However, even with the technique described in Patent Document 1, it is not possible to satisfy recent recent demands for further improvement in cooling capacity, and to sufficiently suppress fluttering of the steel strip, and it is inevitable that the steel sheet has a flaw. There is a problem that the structure of the cooling box is complicated and requires a lot of labor for maintenance.
JP 2004-307904 A

  The present inventors have solved the above-mentioned problems of the prior art, and suppressed the fluttering (vibration) of the steel strip to preferably less than 200 mm, improving the plate-passability during cooling and preventing the occurrence of three-piece flaws in the steel strip. An object of the present invention is to propose a steel strip cooling apparatus suitable for continuous hot dip galvanizing equipment.

In order to achieve the above-described problems, the present inventors diligently studied factors affecting the occurrence of flapping (vibration) during steel strip cooling. As a result, it was found that the fluttering of the steel strip was drastically reduced during cooling by blowing gas using a plurality of pipe pairs instead of a pair of box-type cooling boxes. The present invention has been completed based on such findings and further studies. That is, the gist of the present invention is as follows.
(1) A steel strip cooling device having a pair of chambers for supplying a cooling medium, and a plurality of pairs of pipes of equal length W connected to both ends of the pair of chambers, for cooling a traveling steel strip. The pair of chambers are disposed along the traveling direction of the steel strip at both ends in the width direction across the steel strip, and the pair of pipes are provided facing the plate thickness direction across the steel strip. In addition, a plurality of pairs are provided with a predetermined separation distance L that is equal in the traveling direction of the steel strip, and each of the two pipes constituting the pipe pair has a plurality of holes having a predetermined size. Jo or predetermined width slit-shaped air outlet of Article having the Ri name provided to be injected cooling medium to the steel strip surface, and the total area a before Symbol air outlet, the distance between the pipe-to-L Is the following formula (1)
A ≦ α × {L × W × (n−1)} (1)
(Where A: total area of outlets (mm ² ), L: separation distance between pipe pairs (mm), W: length of pipe pairs (mm), n: number of pipe pairs, α: equipment coefficient = 0.02 )
A steel strip cooling device characterized by satisfying

  According to the present invention, the fluttering of the steel strip can be suppressed to be small, the occurrence of scratches is prevented, the yield is improved, the amount of cooling medium blown out can be increased, the cooling capacity is improved, and the production efficiency is improved. There are remarkable effects in the industry.

As shown in FIG. 1, the steel strip cooling device 10 of the present invention basically includes a pair of chambers 1 and 1 and a plurality of pipe pairs 2, and cools the traveling steel strip S. The pair of chambers are arranged along the traveling direction of the steel strip on both ends in the width direction with the steel strip S traveling in the vertical direction interposed therebetween, and supplies a cooling medium for cooling the steel strip. The cooling medium used in the present invention is preferably a gas such as air or nitrogen gas whose pressure is increased to about 250 to 400 mmH ₂ O by a fan or the like.

  Both ends of two pipes 2a and 2a constituting the pipe pair 2 are connected to the pair of chambers 1 and 1, respectively, so that a cooling medium can be supplied to the pipes. The two pipes 2a, 2a constituting the pipe pair 2 are opposed to each other in the plate thickness direction with the traveling steel strip S interposed therebetween, and are provided apart from the steel strip by a predetermined interval H. The predetermined interval H is preferably about 100 to 200 mm. If the separation interval is too larger than the predetermined interval, the collision pressure between the gas to be blown out and the steel strip will be reduced, and it will not be possible to expect a desired cooling capacity. On the other hand, if it is too narrow, even if a slight vibration occurs in the steel strip, it is unavoidable to generate a thread.

  Each of the two pipes 2a, 2a constituting the pipe pair is provided with a hole-like outlet 3 having a predetermined size as shown in FIG. 2, and blows out gas toward the surface of the steel strip. Made possible. In addition, it may be a slit-shaped outlet having a predetermined width instead of the hole shape. The size of the hole or slit is appropriately determined according to the desired cooling capacity, but if the cooling capacity is about 150 to 300 kcal / h · ° C, the hole of 10 to 20 mmφ is connected to the width direction of the steel strip (pipe length It is preferable that the slits are provided at a pitch of 50 to 150 mm along the vertical direction) or slits having a width of 10 to 15 mm. If it deviates from the above-mentioned size, the output of the fan for obtaining the same cooling effect increases. In addition, the installation angle of the hole or slit provided in the pipe may be an angle that is normally perpendicular to the steel strip, but may be an angle other than vertical depending on the installation location.

A plurality of pairs of pipes 2 are provided with a predetermined separation distance L in the steel strip traveling direction. The distance L between the pair of pipes is the amount of gas to be blown, that is, the relationship with the total area A of the plurality of outlets 3 provided in one pipe, the following equation (1) A ≦ α × {L × W × (n -1)} ......... (1)
(Here, A: total area of outlets (mm ² ), L: separation distance between pipe pairs (mm), W: length of pipe pair in width direction of steel strip (mm), n: number of pipe pairs, α: Equipment coefficient)
It is preferable to determine so as to satisfy. Note that the total area A of the outlet is the sum of the areas of the outlet provided in one pipe of the pipe pair, W is the length (mm) of the pipe pair, and {L × W × (n -1)} represents the area of a space formed between a plurality of pipe pairs, and means the dischargeable area of the gas (cooling medium) bounced back by the steel strip. α is a device coefficient, which is about 0.02 in the cooling device of the present invention.

By selecting the separation distance L between the pipe pairs and the number n of the pipe pairs so as to satisfy the formula (1), the outflow balance of the blown out cooling medium (gas) is stabilized, and the flapping of the steel strip occurs during cooling. Can be prevented. If the expression (1) is not satisfied, the outflow balance of the blown-out gas is broken and the steel strip fluttering occurs.
The steel strip cooling device of the present invention is not limited to hot dip galvanizing equipment, and can be suitably used in continuous annealing equipment and the like. It should be noted that a plurality of steel strip cooling devices of the present invention may be provided in series along the steel strip traveling direction in accordance with the desired cooling zone length.

The cold-rolled steel strip (plate thickness: 0.75 mm) was hot dip galvanized using a continuous hot dip galvanizing facility.
The steel strip is heated to 780 ° C., soaked, cooled to 470 ° C., then immersed in a hot dip galvanizing bath to form a hot dip galvanized film, and then using the steel strip cooling device shown in FIG. Air was blown onto the steel strip and cooled to 110 to 115 ° C. to obtain an example of the present invention. The distance H between the steel strip S and the pipe 2a was 100 mm. The blown air was assumed to have been increased to a plenum pressure of 400 mmH ₂ O (100% of the fan speed) with a fan. The plurality of outlets provided in the pipe had a hole diameter of 16.5 mmφ, a pitch of 100 mm, and an angle of 90 °. The distance L between the pipe pairs was 100 mm, the length W of the pipe pairs was 2200 mm, and 31 pipe pairs were installed. The total area A of the outlet is 125878.9 mm ² , and α {L × W × (n−1)} is 132000 mm ² when α is 0.02, satisfying the expression (1).

On the other hand, the steel strip after hot-dip galvanizing was similarly cooled using the steel strip cooling device of FIG. 3 to obtain a conventional example. In the cooling device of FIG. 3, a pair of box-type cooling boxes are arranged with a steel strip in between, and a plurality of outlets are provided in the cooling box. The number of cooling boxes was two, and the total length of the cooling zone was the same as in the example of the present invention. The sizes of the plurality of outlets are the same as those in the present invention example in terms of hole diameter, pitch, and number. The blown air was increased by a fan to a plenum pressure of 300 mmH ₂ O (60% of the fan specification speed).

  In the example of the present invention, the fluttering <vibration> of the steel strip was suppressed to less than 200 mm regardless of the improvement of the cooling ability of the cooling zone, and there was no generation of a thread in the steel strip. On the other hand, in the conventional example, the fluttering <vibration> of the steel strip was 200 mm or more.

It is a schematic diagram which shows the outline of the cooling device of the steel strip of this invention. It is explanatory drawing which shows typically the outline | summary of the blower outlet vicinity provided in the pipe. It is a schematic diagram which shows an example of the cooling device of the conventional steel strip.

Explanation of symbols

1 Chamber 2 Pipe pair
2a Pipe 3 outlet
10 Cooling device
11 Cooling box
12 nozzles

Claims (1)

A pair of chambers for supplying a cooling medium, a plurality of pairs of pipes of equal length W connected to both ends of the pair of chambers, and a steel strip cooling device for cooling a traveling steel strip, A pair of chambers are disposed along the traveling direction of the steel strip at both ends in the width direction across the steel strip, and the pipe pair is provided facing the plate thickness direction across the steel strip, A plurality of pairs are provided with a predetermined distance L that is equal in the traveling direction of the steel strip, and each of the two pipes constituting the pipe pair has a plurality of holes having a predetermined size or a predetermined shape. Ri slit-shaped air outlet of Article having a width the name provided to allow injecting a cooling medium to the steel strip surface,
A total area A of the air outlet, the distance L between the pipe pair, the following (1) cooling system of the steel strip, characterized that you satisfied expression.
Record
A ≦ α × {L × W × (n−1)} (1)
Here, A: Total area of outlet (mm ² )
L: Distance between pipe pairs (mm)
W: Length of pipe pair (mm)
n: Number of pipe pairs
α: Device coefficient = 0.02

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