KR100402133B1 - Apparatus for controlling width-directional temperature of hot plate - Google Patents

Abstract

The present invention is to provide a widthwise temperature control device for a high temperature plate, the present invention is to provide a cooling device of the high temperature plate (1) exiting the rolling mill, in the center using a cooling device (4), both edges There are a plurality of independent modules (pneumatically operated flow control valve 9, buffer tank 10 for preventing pressure changes at the front end of the valve, and a double diaphragm 12 inside, which enable flow control. By installing 8), it is possible to change the flow rate of the upper cooling water in the width direction by actively coping with the width change of the hot plate passing through the cooling zone after exiting the rolling mill from the steel mill.

As described above, the apparatus for controlling the widthwise temperature of the hot plate according to the present invention includes an optional upper widthwise cooling installation 7 composed of a plurality of independent modules 8 which are not affected by ambient conditions such as high temperature and steam. It is installed at both edges to control the flow rate of each module to extend the width control range, to ensure uniform cooling in the width direction, and to reduce the material deviation in the width direction so that the quality of the product can be improved. Will be.

Description

Apparatus for controlling width-directional temperature of hot plate}

The present invention relates to a width direction temperature control apparatus of a high temperature plate, in particular, to actively change the width of the high temperature plate (1) passing through the cooling zone after exiting the rolling mill in the steel mill to vary the flow rate of the upper cooling water in the width direction The present invention relates to a widthwise temperature control device for a high temperature flat plate suitable for use.

In the conventional hot rolled steel sheet production process, the upper cooling impingement water stream 11 is injected into a flat plate to cool the flat plate in 15 to 16 unit facilities composed of hairpin lamina or the like. Since the upper cooling apparatus 4 applied in the prior art has a uniform flow rate in the width direction, the retention coolant formed on the upper surface of the high temperature flat plate 1 is concentrated on the edge portion, resulting in a problem that the edge portion is overcooled.

1 is a graph showing that excessive temperature rise occurs due to a general widthwise uniform temperature control failure.

Therefore, conventionally, the edge mask 3 is installed in the existing cooling facility 4 to block the upper cooling water flow 11 partially against the edge portion, thereby controlling the supercooling of the edge portion.

Figure 2 is an operation of the edge mask equipment for the widthwise temperature control of the conventional hot plate, Figure 3 is a plan view of the edge mask equipment for the widthwise temperature control of the conventional hot plate.

However, the conventional control by the edge mask has a problem that there is no correspondence to various width changes because the operation of the edge mask is set by the predetermined length (50, 100, 150mm, etc. in the edge portion). Therefore, there is a problem that only a certain temperature is compensated for a certain width of the steel sheet, and therefore, an edge temperature is abnormally high.

In addition, due to a large amount of water vapor and high temperature generated during the cooling of the high temperature plate, the control motor 2, the chain 5, and the screw shaft 6 of the edge mask installation exposed to the outside are corroded, so that accurate control is impossible. If it does not occur, the widthwise uniform cooling does not occur, and furthermore, there is a problem of accelerating the widthwise material deviation.

Therefore, the present invention has been proposed to solve the conventional problems as described above, an object of the present invention is to actively cope with the width change of the high temperature plate passing through the cooling zone after exiting the rolling mill in the steel mill in the upper direction in the width direction The present invention provides a widthwise temperature control device for a high temperature plate capable of varying cooling water flow rate and a method thereof.

In order to achieve the above object, the width direction temperature control apparatus of a high temperature plate according to an embodiment of the present invention,

In the cooling installation of the high temperature plate 1 which exited the rolling mill, the cooling installation 4 is used in the middle, and the flow control valve 9 which operates by pneumatic pressure at both edges, and the pressure change in the valve front end are prevented. The buffer tank 10 and the inside is composed of a double diaphragm 12 is characterized in that the technical configuration consisting of a plurality of independent modules (8) to enable the flow control.

Width direction temperature control method of the high temperature plate according to an embodiment of the present invention to achieve the above object,

When the width direction flow rate control is performed with respect to the hot plate 1 which passes through a cooling stand after exiting a rolling mill, it adjusts the flow volume of the edge part of the said hot plate 1 in the technical configuration.

1 is a graph showing that excessive temperature rise occurs due to a general widthwise uniform temperature control failure,

Figure 2 is an operation of the edge mask equipment for controlling the width direction of the conventional high temperature steel sheet,

3 is a plan view of an edge mask installation for widthwise temperature control of a conventional hot plate;

4 is a schematic diagram of an optional upper widthwise cooling installation of a widthwise temperature control device of a high temperature plate according to an embodiment of the present invention;

5 is a block diagram illustrating a unit module of an optional upper lateral cooling apparatus of a width direction temperature control apparatus of a high temperature flat plate according to an embodiment of the present invention;

6 is a graph showing a schematic example showing the widthwise cooling water distribution for the widthwise temperature control of the hot plate according to an embodiment of the present invention,

7 is an overall configuration diagram of an optional upper widthwise cooling installation of the widthwise temperature control device of the hot plate according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

1: high temperature plate 3: edge mask

4: conventional cooling equipment 5: edge mask chain

6: edge mask screw shaft 7: optional upper widthwise cooling installation

8: Module of the optional upper widthwise cooling installation

9: flow control valve 11: upper cooling water

Hereinafter, with reference to the accompanying drawings an embodiment according to the technical idea of the width direction temperature control device and a method of the present invention hot plate as follows.

First, Figure 4 is a schematic diagram of the selective upper width direction cooling installation of the width direction temperature control apparatus of a high temperature plate according to an embodiment of the present invention.

Thus, the existing cooling system 4 for upper cooling is divided into three zones, and the following optional upper cooling water widthwise cooling system 7 is installed at both edges.

That is, Fig. 4 shows a conceptual diagram of the installation of the optional upper cooling system 7 at both edges using the existing cooling system in the middle of the hot plate traveling direction. The optional upper widthwise cooling installation installed at the edge portion consists of a number (n) of independent modules 8 (denoted 'm' in FIG. 4).

FIG. 5 is a schematic diagram showing the configuration of each independent module 8 as a unit module configuration diagram of an optional upper widthwise cooling apparatus of a widthwise temperature control apparatus of a hot plate according to an embodiment of the present invention.

Thus, the flow rate control for each module is made by each flow control valve 9 operated by pneumatic pressure, and the buffer tank 10 is installed to prevent the pressure change at the front end of the valve when the coolant is supplied in the width direction. . The inside of the module is provided with a double diaphragm 12 to ensure a stable flow of water.

As such, the independent module and the control valve 9 can control the flow rate in the width direction without being affected by the conditions in which the direct exposure to the hot plate and the steam occurs.

Figure 6 is a graph showing a schematic example showing the widthwise cooling water distribution for the widthwise temperature control of the hot plate according to an embodiment of the present invention.

Thus, '■' of FIG. 6 shows the main water widthwise flow distribution of the selective upper widthwise cooling installation 7 composed of a plurality of modules, and the dotted line shows the width when the existing edge mask 3 and the existing cooling installation 4 are used. Show the direction flow distribution.

If it is assumed that the main flow rate control by the existing edge mask equipment is made in the intermediate position of the module 5, the width direction flow control can be performed by pouring 50% of the flow rate in the module 5 in the present invention.

In this method, since the width direction temperature control range is limited by setting and operating the usage amount by a predetermined length (50, 100, 150 mm, etc.) in the existing edge mask equipment, the width direction flow control is variable. The width direction temperature control range is varied.

7 is an overall configuration diagram of an optional upper widthwise cooling installation of the widthwise temperature control device of the hot plate according to an embodiment of the present invention.

In FIG. 7, the water supply of the upper cooling water flow 11 of the present invention consisting of a plurality of modules and a conventional cooling installation 4 in the width direction with respect to the hot plate 1 actually exiting the rolling mill is shown schematically.

As described above, the present invention is to actively cope with the width change of the hot plate passing through the cooling zone after exiting the rolling mill in the steel mill to vary the flow rate of the upper cooling water in the width direction.

Although the preferred embodiment of the present invention has been described above, the present invention may use various changes, modifications, and equivalents. It is clear that the present invention can be applied in the same manner by appropriately modifying the above embodiments. Accordingly, the above description does not limit the scope of the invention as defined by the limitations of the following claims.

As described above, the apparatus for controlling the widthwise temperature of the high temperature plate according to the present invention and the method thereof include an optional upper widthwise cooling system composed of a plurality of independent modules 8 which are not affected by ambient conditions such as high temperature and steam. 7) is installed at both edges to control the flow rate of each module to expand the width control range, to make the cooling uniform in the width direction, and to reduce the material deviation in the width direction to improve the product quality. It can be effective.

Claims (2)

In the cooling installation of the high temperature plate 1 exiting the rolling mill, In the middle, a cooling system 4 is used, and at both edges, a flow control valve 9 operated by pneumatic pressure, a buffer tank 10 for preventing pressure changes at the front end of the valve, and a double diaphragm 12 inside. Width direction temperature control device of the high temperature plate, characterized in that a plurality of independent modules (8) is configured to enable the flow control. delete