JPS63168215A - Cooler for metal sheet - Google Patents

Abstract

PURPOSE:To uniformize cooling for a metal sheet and to prevent deformation of the sheet by installing an overflow type slit nozzle in the rear side between upper rolls and also installing a cooling water sucking nozzle in adjacency of the front side upper roll. CONSTITUTION:An upper cooling water nozzle 21 consisting of an overflow type slit nozzle is installed at the rear side in the metal sheet transfer direction between upper rolls 12, 12 and a slit nozzle part 21b is also installed on the bottom of a header part 21a. A water sucking pipe 25 having a sucking nozzle 26 is installed along the roll 12 in adjacency of the front side upper roll 12. Cooling water supplied from the slit nozzle 21b forms a laminar jet flow covering the whole width of a metal sheet 11 and cools the sheet 11. Cooling for the sheet 11 is uniformized and deformation of the sheet 11 is prevented because the cooling water on the sheet 11 is suddenly removed by the sucking nozzle 26.

Description

DETAILED DESCRIPTION OF THE INVENTION "Field of Industrial Application" The present invention relates to a cooling device for cooling a high-temperature metal plate, such as a shoulder plate immediately after rolling.

``Prior Art'' As this type of cooling device, the one shown in FIG. 3 has been widely used. In FIG. 3, reference numeral 1 is a metal plate to be cooled, and 2.3 is a pair of upper and lower rolls that sandwich the metal plate 1 from above and below. A plurality of sets (only two sets are shown in FIG. 3) of the upper roll 2 and the lower roll 3 are provided at predetermined intervals along the transport direction of the metal plate (from left to right in the figure). The metal plate l is transferred by rotating each roll 2.3.

Between the upper rolls 2 and 2 adjacent to each other and the lower roll 3,
Spray vibes 4 and 5 are arranged between the spray vibes 4 and 5 at positions facing each other with the metal plate 1 in between, and cooling water is fed under pressure to these spray vibes 4 and 5 from a water supply source (not shown). It has become. And spray vibe 4
, 5, the cooling water is sent to the upper spray vibrator 4.
From the numerous nozzle holes formed on the lower surface of the metal plate l and the upper surface of the lower spray vibe 5, rod-shaped water streams are discharged as shown in FIG. is sprayed onto the metal plate l, thereby cooling the metal plate l.

"Problems to be Solved by the Invention" By the way, the above-mentioned conventional cooling device has the following problems.

■Since the cooling water discharged from the nozzle hole of the spray pipe 4.5 is a rod-shaped water stream, the part directly hit by this water stream is cooled excessively compared to other parts, causing so-called cold spots on the metal plate l. will occur.

(2) Cooling water sprayed onto the metal plate 1 from the spray pipes 4, 5 flows on the surface of the metal plate 1 toward the upper rolls 2, 2 and the lower rolls 3, 3, as shown in FIG. 3(A). Then, it falls as it is on the bottom surface of the metal plate l, but
On the upper surface of the metal plate 1, as shown in FIG. 3(b), the liquid is stopped by the upper roll 2.2 and flows in the width direction of the metal plate 1, and then flows down from the edge of the plate. For this reason, a large amount of cooling water comes into contact with the edge portion of the metal plate 1 compared to the center portion of the metal plate 1, and the edge portion of the plate is cooled excessively, causing uneven cooling and deforming the metal plate 1. Sometimes.

■The flow rate of cooling water discharged from the nozzle holes is controlled by changing the water pressure of the cooling water sent to the spray vibes 4 and 5. However, if the water pressure is too low, the discharged water will not become a rod-shaped water flow, so the flow rate should be set to the maximum. The discharge flow rate can only be reduced to about 1/2 to 1/3, and the flow rate control range is narrow.

■Since the upper spray vibe 4 has a nozzle hole on the bottom surface, even if you stop pumping the cooling water to the upper spray vibe 4 after cooling is complete, the discharge will not stop until all the internal cooling water has flowed out. , Drainage is poor.

"Means for Solving the Problems" In order to solve the above problems, the present invention provides a plurality of pairs of upper rolls and lower rolls that transport metal plates while sandwiching them from above and below, and upper rolls adjacent to each other. an upper cooling water nozzle disposed near the upper roll on the rear side in the direction in which the metal plates are transferred between the two, and discharging cooling water onto the upper surface of the metal plate; a water absorption device disposed near the upper roll to suck the cooling water discharged by the upper cooling water nozzle from the upper surface of the metal plate; and a water absorption device disposed in the center between the adjacent lower rolls to suck the cooling water from the upper surface of the metal plate. a lower cooling water nozzle that discharges water toward the lower surface of the metal plate; The overflow type slit nozzle has a slit nozzle section located at the header section for discharging overflow water of the cooling water supplied to the header section in the transfer direction of the metal plate, and the water absorption device is arranged along the upper roll. and a water suction nozzle that is attached to the water suction pipe and sucks cooling water from the vicinity of the contact portion between the upper roll and the metal plate, the upper roll, the upper cooling water nozzle, The water absorption device is characterized in that it is movable up and down with respect to the lower roll.

"Function" In the cooling device of the present invention, while a metal plate is being transferred between a pair of upper and lower rolls, cooling water is applied to the upper and lower surfaces of the metal plate from an upper cooling water nozzle and a lower cooling water nozzle, respectively. Spray and cool. The upper cooling water nozzle is an overflow type slit nozzle,
Overflow water of the cooling water supplied to the header section is discharged from near the upper roll on the front side in the metal plate transfer direction in the metal plate transfer direction. Further, the cooling water discharged from the upper cooling water nozzle and flowing toward the upper roll on the front side is sucked and drained by a water absorption device near the upper roll.

"Embodiment" An embodiment of the present invention will be described below with reference to FIGS. 1 and 2.

FIG. 1 is a front view showing a schematic configuration of the cooling device of this embodiment, and FIG. 2 is a fixed view taken along the line 1--2 in FIG.

In the figure, reference numeral 11 is a metal plate to be cooled, and 12 and 13 are a pair of upper and lower rolls that sandwich the metal plate 11 from above and below. A plurality of sets (only two sets are shown in FIG. 2) of these upper rolls 12 and lower rolls 13 are provided along the transport direction of the metal plate 11, and each roll 12, 12, 13 .
By synchronously rotating the metal plate II
is transferred from left to right in FIG. The lower roll 13.13 has both ends fixed on the frame 14.
．． 14, and is fixedly provided on the floor surface, and the upper roll 12.12 is supported by mounting frames 15, 15, a lifting frame I6, and a lifting drive source 1 such as a hydraulic or pneumatic cylinder.
The upper roll is supported by the concave frame I8 via 7.17, and is driven by the lifting drive source 17.17! 2.12 can be raised and lowered relative to the lower roll 13.13.

Further, as shown in FIG. 2, the lower rolls 13 adjacent to each other
A lower cooling water nozzle 20 is provided in the center between the upper rolls 12 and 13, and an upper cooling water nozzle 20 is provided near the upper roll 12 on the rear side (on the left side in FIG. 2) of the metal plate transfer direction between the upper rolls 12 and 12. A water nozzle 21 is arranged. The lower cooling water nozzle 20 has a slit nozzle part 20b, which has a width slightly longer than the width of the metal plate 11, attached to the upper part of a tubular header part 20a, which is slightly longer than the entire length of the lower roll 13, and projects upward. A lower cooling water supply pipe 22 is connected to the lower part of the header part 20a, and cooling water, which is pumped from a supply source (not shown) through the supply pipe 22, is supplied from the slit nozzle part 20b to the lower surface of the metal plate 11 over its entire width. It is designed to be sprayed.

On the other hand, the upper cooling water nozzle 21 is formed into a slit nozzle part 2 having a width slightly longer than the width of the metal plate 11 on the lower surface of a header part 21a having a rectangular cross section that is slightly longer than the entire length of the upper roll summer 2.
1b extends downward and is attached.

An upper cooling water supply pipe 24 is connected to the header part 21a via a connecting pipe 23, so that cooling water is supplied to the header part 21a from a supply source (not shown). In addition, the slit nozzle part 21b has its upper end located at the upper part of the header part Ia, and its lower end part bent in the direction of conveying the metal plate 11, so that the slit nozzle part 21b has an upper end located in the upper part of the header part Ia, and a lower end part of the slit nozzle part 21b. Overflow water of the cooling water is discharged from a position close to the upper surface of the metal plate 11 in the metal plate transport direction.

This upper cooling water nozzle 21 discharges overflow water, and also discharges a water stream from the slit nozzle portion 21b over the entire width of the metal plate 11.
This is a type of so-called overflow type pickpocket or soto nozzle. In this type of nozzle, the water pressure and flow velocity of the discharged water stream are relatively small, so that the discharged water stream has a laminar flow (laminar jet flow).

In addition, between the upper rolls 12 and 12, a water absorption pipe 25 is arranged so as to extend along the upper roll 12 close to the upper roll 12 on the front side in the metal plate transfer direction (on the right side in FIG. 2). A water suction nozzle 26, which is slightly longer than the width of the metal plate 11, is attached to the water suction pipe 25 with its tip positioned near the contact area between the upper roll 12 and the metal plate 11. In addition, both ends of the water suction pipe 25 are connected to water suction headers 27.27, respectively, as shown in FIG.
8.28 are connected and these intake pipes 28.28 are connected to the above-mentioned lifting frame 16 supporting the upper roll 12.12.
It is connected to an exhaust fan 29.29 fixed above. Furthermore, a drain pipe 3 is installed at the bottom of the water absorption header 27.27.
0.30 are installed and extend downward, and those drain pipes 3
A seal trap 31.31 having a predetermined water sealing method is attached to the tip (lower end) of the 0.30 mm.

The above water suction pipe 25, water suction nozzle 26, water suction header 27
．． 27, intake pipes 28, 28, exhaust fan 29°29, drain pipes 30, 30, and seal trap 31.3I are the cooling water discharged from the two-part cooling water nozzle 21 and flowing toward the upper roll 12 on the front side. It constitutes a water absorption device 32 for sucking and draining water from the upper surface of the metal plate 11, and the water absorption header 2 is operated by operating the exhaust fan 29, 29.
7.27 and the inside of the water suction pipe 25 to a predetermined degree of vacuum (for example, about -50 mmAq to -150 mmAq), and suck the cooling water from the water suction nozzle 26 and drain the sucked cooling water from the drain pipe 30.30. It has become. In addition, the drain pipe 30.30 is sealed by the seal trap 31.31 attached to the tip of the drain pipe 30.30.
The water sealing method for Nord Trap 31.31 is to prevent air from flowing in from the exhaust fan 29.29.
(For example, if the vacuum level is 1150mmAQ, the water seal method should be set according to the vacuum level obtained by
It should be about mm).

The lower cooling water nozzle 20 mentioned above is fixedly provided on the floor surface, but the upper cooling water nozzle 21 and the water absorption device 32
Like the upper roll 12.12, it is attached to the lifting frame 16, and can be raised and lowered together with the upper rolls 12 and I2 by driving the lifting drive source 17.17.

In the cooling device with the above configuration, each roll is 12.12°13.
13 to transfer the metal plate II, cooling water is force-fed from a supply source (not shown) to the lower cooling water nozzle 20 at a predetermined water pressure, and no water pressure is applied to the upper cooling water nozzle 21. Supply cooling water at a predetermined flow rate.

At the same time, the exhaust Fxa29.29 is operated to absorb water 125%.
Maintain a predetermined degree of vacuum inside.

As a result, the cooling water force-fed to the lower cooling water nozzle 20 flows from the slit nozzle part 20b to the entire width of the metal plate 11, as shown by the arrow in the figure, and flows into the metal plate work 1.
The sprayed cooling water is sprayed onto the lower surface of the metal plate 11 and falls while flowing toward the lower rolls 13 and 13 on both sides along the lower surface of the metal plate 11.

On the other hand, the cooling water supplied to the header part 21a of the upper cooling water nozzle 21 overflows from the upper end of the slit nozzle part 21b, so that the cooling water flows from the tip of the slit nozzle part 21b to the metal plate 11 as shown by the arrow in the figure. Discharge in the transport direction. The discharged cooling water flows on the upper surface of the metal plate 11 toward the upper roll 12 on the forward side in the transport direction, and when it reaches the contact area between the upper roll 12 and the metal plate 11, it is dammed up there, where it is immediately absorbed by the water absorption nozzle 26. It is sucked into pipe 25 and drained through water suction header 27.27 through drain pipe 30.30.

According to this cooling device, the upper cooling water nozzle 21 and the lower cooling water nozzle 20 each discharge cooling water as a water stream over the entire width of the metal plate 11. There are no cold spots.

In particular, an overflow type slit nozzle with a relatively low discharge water pressure is used as the upper cooling water nozzle 21, and the cooling water is discharged from a position close to the upper surface of the metal plate 11 in the direction of transport. It flows smoothly over the entire width of the upper surface of the metal Vi, 11, so that the entire metal Vi, 11 can be uniformly cooled.

Also, the cooling water discharged from the upper cooling water nozzle 21 and flowing toward the upper roll on the front side in the transfer direction is transferred to the water absorption device 32.
Since the cooling water is sucked from near the contact area between the upper roll I2 and the metal plate 11, the cooling water dammed up by the upper roll 12 does not flow along the upper roll 12 and fall from the edge of the plate. It is also prevented that the metal plate 11 is deformed due to excessive cooling of the plate end.

In addition, since an overflow type slit nozzle is used as the upper cooling water nozzle 21, the amount of discharged water can be easily controlled by changing the amount of water supplied to the header section 21a of the upper cooling water nozzle 21. It is possible to reduce the amount to the maximum discharge flow rate of about 115. Therefore, it is possible to easily set the optimal amount of water over a wide range. Further, when cooling is completed and the supply of cooling water to the upper cooling water nozzle 21 is stopped, the water discharge from the slit nozzle portion 21b is immediately stopped, so that water drains very easily.

Furthermore, in this cooling device, the upper cooling water nozzle 211 and the water absorption device 32 are moved up and down together with the upper roll 12.12, so that depending on the thickness of the metal plate 11 or during maintenance and inspection, by moving them up and down, It can handle metal plates of various thicknesses, and maintenance work can be easily performed.

Furthermore, if the metal plate II does not need to be cooled and only needs to be transferred, the upper roll 12.12 may be pulled up and the lower roll 11.11 may be used to transfer the metal plate II.
The power required for transportation can be saved.

In the above embodiment, each of the slit nozzle portions of the upper and lower cooling water nozzles had a length that spanned the entire width of the metal plate, but the slit nozzle portion was not necessarily limited to this. It may be divided in the width direction.

Furthermore, in the above description, two pairs of upper rolls and lower rolls are provided, and a cooling water nozzle and a water absorption device are provided between them.
Of course, it is also possible to similarly provide a cooling water nozzle and a water absorption device between each set to cool the metal plate in multiple stages. In that case, the amount of discharged cooling water and the amount of water absorbed may be appropriately set for each stage depending on the required cooling conditions.

"Effects of the Invention" As explained in detail above, according to the present invention, the following effects can be obtained.

■ An overflow type slit nozzle is used as the upper cooling water nozzle, and the cooling water is discharged from a position close to the top surface of the metal plate in the transport direction, so that the cooling water flows smoothly over the entire width of the top surface of the metal plate 11. Therefore, the entire metal plate can be uniformly cooled without creating cold spots unlike when a rod-shaped water stream is sprayed from a conventional nozzle hole.

■Equipped with a water absorption device that sucks cooling water from near the contact area between the top roll and the metal plate, so the cooling water dammed up by the top roll does not flow along the top roll and fall from the edge of the plate. Therefore, the metal plate is prevented from being deformed due to excessive cooling of the plate end.

■Since an overflow type slit nozzle is used as the upper cooling water nozzle, the amount of water discharged can be controlled simply by changing the amount of water supplied to the header section of the upper cooling water nozzle, making it easy to set the optimal water amount over a wide range. can. Moreover, if the supply of cooling water is stopped, the water discharge from the slit nozzle part immediately stops, so water drains very easily.

■Since the upper roll, upper cooling water nozzle, and water absorption device are configured to be able to be raised and lowered, they can be moved up and down depending on the thickness of the metal plate or during maintenance inspections, making it possible to handle metal plates of various thicknesses. Also, maintenance and inspection work can be easily performed.

[Brief explanation of the drawing]

1 and 2 show an embodiment of the present invention. FIG. 1 is a front view showing a schematic configuration of the cooling device of this embodiment, and FIG. 2 is a view taken along the line ■-■ in FIG. 1. Try to fixate. FIG. 3 is a diagram showing a schematic configuration of a conventional cooling device,
Of these, (a) is a side view, and (b) is a plan view. ! ■・・・Metal plate, 12・・・Top roll,
I3...lower roll, 17...lifting drive source, 20...lower cooling water nozzle, 21...
...Upper cooling water nozzle, 21a...Header section, 21b...Slit nozzle section, 25...
... Water suction pipe, 26 ... Water absorption nozzle, 32 ...
...Suction device. Applicant Ishikawajima Harima Heavy Industries Co., Ltd. Figure 2 Figure 3 (a) (b)

Claims (1)

[Claims] A plurality of pairs of upper rolls and lower rolls that transfer the metal plate while sandwiching it from above and below are arranged near the upper roll on the rear side in the metal plate transfer direction between the adjacent upper rolls, and are arranged to supply cooling water to the metal plate. An upper cooling water nozzle is disposed near the upper roll on the front side in the metal plate transfer direction between the upper rolls, and the upper cooling water nozzle discharges the cooling water to the upper surface of the metal plate. The upper cooling water nozzle is equipped with a water absorption device that sucks water from the upper surface, and a lower cooling water nozzle that is disposed in the center between adjacent lower rolls and discharges cooling water toward the lower surface of the metal plate. A nozzle is provided with a header portion having a length spanning the entire width of the metal plate, and an upper end portion of which is located inside the header portion to discharge overflow water of the cooling water supplied to the header portion in the direction of conveyance of the metal plate. an overflow type slit nozzle having a slit nozzle part, and the water absorption device includes a water absorption pipe extending along the upper roll, and a water absorption pipe that is attached to the water absorption pipe and cools from the vicinity of the contact area between the upper roll and the metal plate. a water absorption nozzle that sucks water, and the upper roll, the upper cooling water nozzle, and the water absorption device are each movable up and down with respect to the lower roll. cooling system.