KR100942092B1 - Device for reverse guiding the extration slab to heating furnace - Google Patents

Abstract

The present invention in the hot rolling and thick plate process is heated in a heating furnace at a temperature suitable for rolling the slab and then transferred to the rolling mill in the process of an abnormal condition occurs in the equipment to re-heat when the failure occurs in the rolling material An extraction slab reverse charging induction device for reverse charging the slab into a furnace.

Extraction slab reverse charging induction apparatus of the present invention, in the extractor for extracting the slab heated to a high temperature in the heating furnace to transfer to the rolling mill or back-loading the slab into the heating furnace, the conveying direction of the slab 20 of the extractor 50 The stopper slider guide groove 160 is formed on the opposite side of the extractor 50, the slider cylinder 140 is connected to the rear side of the extractor 50, and the stopper slider body groove 150 is formed at both sides, and the stopper moves at one end. A stopper slider 80 having a stopper slider 80 having a fixed member 152 connected to one end of the cylinder 130 and inserted into the stopper slider 80 through the stopper slider guide groove 160. The other end of the 130 is connected to the stopper 90 and the sensor 190 is characterized in that it comprises a stopper body 70 extending in parallel with the rod sequentially coupled.

Furnace, Extractor, Rolling Mill, Charging, Reverse Charging, Induction, Stopper, Slider

Description

Device for reverse guiding the extration slab to heating furnace}

1 is a conventional extraction slab reverse charging operation state diagram,

Figure 2 is the extraction slab reverse charging operation state according to the present invention,

3 is an external perspective view of an extractor installed with a reverse charging apparatus according to the present invention;

4 is a partial cutaway perspective view of the extractor according to the present invention;

Figure 5 is an exploded perspective view of the extraction slab reverse charging guide device according to the present invention.

※ Explanation of symbols about main part of drawing ※

10: furnace 20: slab

30: roller table 40: rolling mill

50: extractor 60: furnace wall protection line

70: stopper body 80: stopper slider

90: stopper 100: spring

110: guide groove 120: assembly bolt

130: stopper moving cylinder 140: slider cylinder

150: stopper slider body groove 160: stopper slider guide groove

170: fork 180: working room                 

190: detection sensor

The present invention relates to a reverse slab charging induction apparatus, and more specifically, the slab, which is a rolled material in hot rolling and thick plate processes, is heated to a temperature suitable for rolling in a heating furnace, and then transferred to a rolling mill in an abnormal state in a facility. The present invention relates to an extraction slab reverse charging induction device for reverse charging the slab into a heating furnace for reheating when a failure occurs in the rolled material.

In hot rolling and thick plate processes, the slabs are heated to a high temperature and then transported and rolled. First, the conventional reverse slab charging operation state will be described with reference to FIG. 1.

In the general rolling process, the slab 20 is installed inside the heating furnace 10, and the slab 20 moving in the zigzag is extracted using the extractor 50, and then transferred to the rolling mill 40 through the roller table 30. The transferred slabs 20 are rolled in the rolling mill 40. When the post-processing failure occurs during the transfer of the slab 20 to the rolling mill 40, the high-temperature slab 20 rolled from the rolling mill 40 is loaded back into the heating furnace 10.

In the reverse charging process, the roller table 30 is controlled to transfer the slab 20 from the rolling mill 40 in the reverse direction, that is, in the direction of the heating furnace 10, and the extracted slab 20 is used by the extractor 50. To enter the heating furnace 10 again.

However, the slab of high heat enters into the heating furnace 10 in the working progress chamber 18, the heating furnace 10, and the extractor 50 in which the central control unit is installed to control the progress of all the work in the conventional reverse charging process. There is no remote induction device in the process of the high temperature slab 20 is damaged by contact with the furnace wall as indicated by the dotted line while passing through the furnace wall protection line (60).

In other words, when the high-temperature slab 20 collides with the furnace wall several times during the passage of the furnace wall protection line 60, a work failure occurs such that the extractor equipment is damaged, and the quality of the slab is degraded. There were problems such as burn injury, slab extraction due to collision, and productivity decrease due to delayed loading.

The present invention is to solve the above problems, an object of the present invention is an abnormal state in the equipment in the process of rolling the slab which is a rolled material in a hot rolling and thick plate process in a heating furnace after heating to a temperature suitable for rolling and rolling in a rolling mill Is to provide an extraction slab reverse charging guide device for reverse charging the slab into the heating furnace for reheating when a failure occurs in the rolled material.

Extraction slab back-loading induction apparatus of the present invention for achieving the above object, in the extractor for extracting the slab heated to a high temperature in the heating furnace to transfer to the rolling mill or back-loading the slab into the heating furnace, the slab transfer direction of the extractor The stopper slider guide groove is formed on the opposite side of the stopper, and the slider cylinder is connected to the rear side of the extractor, and a stopper body groove is formed on both sides, and a stopper slider having a fixing member connected to one end of the stopper moving cylinder at one end thereof. The stopper slider is inserted into the stopper slider through the stopper slider guide groove and is connected to the other end of the stopper slider, and includes a stopper body in which a rod in which a stopper, a sensor, and a spring are sequentially coupled in parallel is extended. It is characterized by.

Hereinafter, the extraction slab reverse charging induction apparatus of the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 shows the operating state of the extraction slab back-loading induction apparatus according to the present invention. Due to the process failure, the back loading induction process of the slab 20 is started, and when the slab 20 is back loaded into the heating furnace 10, the slab 20 is transferred back to the extractor 50 through the roller table 30. ), The slab 20 is stopped by the stopper body 70 (exactly a stopper) provided on the opposite side (right side in the drawing) of the extractor 50. The stopper body 70 will be described later. At this time, the contact between the slab 20 and the stopper body 70 is detected by a detection sensor (not shown), and a signal is transmitted to the upper controller. After detection of this signal, the extractor 50 is activated.

The slab 20 stopped by the stopper body 70 is back loaded into the heating furnace 10 by the operation of the extractor 50 itself, and is then reloaded into the rolling mill 40 after being heated again. Referring back to FIG. 2 when the slab 20 is back loaded into the heating furnace 10, the slab 20 is positioned by the portion connected to the stopper body 70 so that the slab 20 is transported without colliding with the conventional furnace wall protection line 60. It can be solved. At the time of reverse loading of the slab 20, all control states output a control command from the work progress chamber 180.                     

An external perspective view of the extractor 50 according to the invention is shown in FIG. 3.

The appearance of the extractor 50 is similar to that of the prior art, and the stopper body 70 is positioned adjacent to the side of the forks 170 for conveying the slab (the opposite position of the side into which the slab 20 is conveyed). The stopper 90 is positioned at the end of the rod extending from the stopper body 70. The rod extends in parallel with the stopper body 70. The stopper 90 coupled to the rod is in direct contact with the slab 20 and serves to stop the slab 20.

When the slab 20 and the stopper 90 which are back-loaded come into contact with each other, a detection sensor 190 installed behind the stopper 90 detects this and performs control. This control operation is preferably controlled in a batch with the entire work process in the upper control unit installed in the work progress chamber 180. The rear of the sensor 190 is provided with a spring (not shown) as a shock absorbing material for shock absorption.

FIG. 4 is a partial cutaway perspective view of the extractor 50 of FIG. 3, showing the stopper body 70 and the stopper slider 80 for receiving the stopper body 70. A stopper slider guide groove 160 is formed on one side of the extractor 50 according to the present invention. The stopper body 70 moves through the stopper slider guide groove 160.

A stopper slider 80 is provided inside the extractor 50. The stopper slider 80 is for receiving the stopper body 70 to be movable. In addition, the stopper slider 80 is coupled to a pair of slider cylinders 140 to move forward. The slider cylinder 140 is collectively controlled along with other processes by the upper controller.

The detailed structure of the stopper slider 80 and the stopper body 70 as described above is illustrated in FIG. 5.

As shown, the stopper body 70 is inserted into the stopper slider 80, and one end of the stopper moving cylinder 130 is connected to the stopper 90 and the sensing sensor 190 in parallel with the body. The rod to which the spring 100 is sequentially coupled is extended. The stopper moving cylinder 130 has one end connected to the stopper body 70 and the other end connected to the fixing member 152 formed on the stopper slider 80. Therefore, when the stopper moving cylinder 130 is expanded, the stopper body 70 moves along the inside of the stopper slider 80.

In addition, the stopper slider 80 has a distance adjusted by the slider cylinder 140, and an assembly bolt 120 is installed through the outer surface thereof, and a stopper slider body groove 150 is formed therein, and a fixing member 152 at the end thereof. Is formed.

The assembly bolt 120 penetrates into the stopper slider 80 and protrudes. Thus assembled bolt 120 is coupled to the guide groove 110 formed in the stopper body (70). The stopper movement cylinder 130 is actuated by the assembly bolt 120 and the guide groove 110 to restrict the departure of the operation region when the stopper body 70 moves.

The operating state of the extraction slab reverse charging induction apparatus of the present invention having the configuration as described above will be described.

If a process failure occurs during the rolling of the high temperature slab 20 in the rolling mill 40, the high temperature slab 20 is transferred to the fork 170 of the extractor 50 using the roller table 30 for reverse charging. At this time, the stopper body 70 and the slider cylinder 140 installed inside the extractor 50 are operated to move the stopper slider 80 forward and stand by. This standby state is controlled according to the width and length of the slab 20 to be back loaded. The control signal is output from the host controller.

In order to reverse load, the upper control unit reduces the rotational speed of the roller table 30, advancing the high-temperature slab 20 in the direction of the stopper 90 and the sensing sensor 190, and closely adhering, and the heating furnace 1 in the standby state. When the stable induction setting of the furnace wall protection line 60 is completed, the operation is performed in the reverse order to the normal position again, the standby and the extractor 50 is raised to move the high-temperature slab 20 into the heating furnace 10 1 The reloading of falcon slabs is completed. When the slab 20 is moved again in the standby state and sensed by the detection sensor 190, the extractor 50 is operated to reversely charge the inside of the heating furnace 10.

According to the present invention, the high-temperature reverse-loading slab generated during the post-process and rolling process is quickly and safely reverse-loaded into the furnace cracking zone to reduce slab thermal deviation, improve the high-temperature slab quality, and improve the equipment damage and safety work. have.

Claims (3)

In the extractor for extracting the slab heated to a high temperature in the furnace to transfer to the rolling mill or back-loading the slab into the furnace, The stopper slider guide groove 160 is formed on the opposite side of the slab 20 in the transport direction of the extractor 50, and the slider cylinder 140 is connected to the rear side of the extractor 50, and the stopper body groove is formed on both sides of the extractor 50. A stopper slider (80) is formed and a stopper slider (80) having a fixing member (152) to which one end of the stopper moving cylinder (130) is connected to one side end thereof is provided, and the stopper slider (through the stopper slider guide groove (160) The other end of the stopper moving cylinder 130 is connected to the inside of the 80 and includes a stopper body 70 in which a rod in which the stopper 90 and the detection sensor 190 are sequentially coupled extends in parallel. Extractive slab back-loading induction device. The method of claim 1, The assembly bolt 120 is installed through the outer surface of the stopper slider 80, and the guide groove 110 is formed on the surface of the stopper body 70 so that the stopper body 70 is separated from the operating area. Extraction slab reverse charging guide device, characterized in that to prevent. The method of claim 1, Extraction slab back-loading induction apparatus, characterized in that the spring 100 having an elastic force is installed on the rear of the sensor sensor 190 to mitigate the impact upon contact with the slab (20).

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