KR19990017043U - Sub-material input pipe penetration device of converter - Google Patents

Abstract

The present invention automatically removes obstacles formed in the input pipe when the raw materials are added in order to adjust the temperature and components of the molten steel contained in the furnace in the converter's steelmaking process of refining molten iron into molten steel. To a through-material feed pipe penetration device of the converter

In other words, when the blower works in the converter, a sensing member is installed in the line where the subsidiary material is inputted so that it can be detected early in the event of a failure, and a penetrating device is installed in order to prevent the blockage of the subsidiary material input liner. According to the configuration, it is possible to ensure the stability of the blowing operation and to smoothly add the subsidiary materials.

Description

Sub-material input pipe penetration device of converter

The present invention is an obstacle formed in the input pipe when inputting the raw material to adjust the temperature and components of the molten steel contained in the furnace in the converter steelmaking process, more specifically in the converter steelmaking process of refining the molten iron to molten steel The present invention relates to a penetrating device for the subsidiary material input pipe of the converter which automatically removes the urea so as to smoothly input the subsidiary material.

In general, in the converter, which is a steelmaking process for refining molten iron with molten steel, adjustment of the molten steel temperature and components in the furnace was essential, and as part of the input of the raw material (FLUX) into the furnace of the furnace, the general apparatus and operation thereof The flow is as shown in FIG.

That is, when the input amount for each raw material to be input from the input device 1 is input, the input signal is controlled by the central processing unit 2 to operate the feeder 3 'of the subsidiary hearth hopper 3, and When a predetermined amount of material stored in the hearth hopper 3 is ejected by the operation, the load cell 4, 4 ', which measures the amount of material change in the hearth hopper, senses the weight and sends it to the converter 5 as a resistance value. do.

The converter 5 converts the resistance value into a volt value and inputs it to the central processing unit 2, and the central processing unit 2 has a volt value corresponding to the amount of sub-material already input from the input device 1. When it is read, the feeder 3 'of the sub raw material hopper 3 is stopped to complete a series of sub raw material input operations.

On the other hand, the raw material ejected from the feeder (3 ') is introduced into the furnace of the converter 10 through the input liner and the sub-material jacket (6), wherein the refining operation is carried out through the oxygen lance 8 as shown in FIG. As the slag castle in the converter furnace is now scattered in the process of blowing, the current (g) is accumulated and the accumulation of the current causes the entrance of the sub-material jacket 6 to be blocked, as shown in FIG. 3. A large amount (about 5 tons) of raw materials to be added are different from the input liner 7 '.

Due to the above phenomenon, it is not possible to add the subsidiary materials during the converter refining operation for refining the molten iron to molten steel, resulting in a problem that the temperature and composition of the molten steel face an unpredictable state.

At this time, the operator who works on the input of the subsidiary materials in the central cab can check the input of the subsidiary materials on the software (SOFT WARE) through the computer network. Since it could not be detected, it eventually caused the quality deterioration due to the temperature and component defects of the molten steel, and the air supply cuts a portion of the input liner as shown in FIG. 4 and then pours the raw material filled in the input liner. As the worker works manually to remove the accumulated slag now, it increases the fatigue of the worker and causes the production to be interrupted due to the blockage of the raw material input line during the converter work. There was a problem such as being.

The present invention has been devised in view of the problems caused by the clogging of the conventional secondary raw material input line as described above, the purpose of which is to convert the secondary raw material to be introduced into the furnace in the converter steelmaking process smoothly to prevent the input of the converter. It is to provide a subsidiary material input pipe penetrating device.

It is another object of the present invention to provide a converter feedstock through-pipe of the converter to improve productivity and quality by significantly reducing downtime by quickly and safely removing obstacles in the event of blockage of the feedstock input line.

The present invention to achieve this purpose is to install a sensing member to detect the early in the event of a failure in the line to feed the sub-material during the work in the converter, and to prevent the blockage of the feed-in liner in advance. According to the configuration of the penetrating device to make the pipe, it is characterized in that the stability of the blowing operation and smooth input of the subsidiary materials.

1 is an overall configuration diagram showing a process of inputting a subsidiary material of a typical converter;

Figure 2 is a schematic diagram for explaining the blocked state of the conventional subsidiary input line,

3 is a configuration diagram showing a problem due to the clogging of the input line,

4 is a configuration diagram showing an example for solving the blockage of the conventional input line,

5 is a configuration diagram showing an installation state of the subsidiary material input pipe penetrating apparatus of an embodiment of the present invention,

6 and 7 is an exploded perspective view and a coupled perspective view of the penetrating device of the embodiment of the present invention,

8 is a cross-sectional configuration of the sensing member of the present invention.

<Description of Symbols for Main Parts of Drawings>

1: input device 2: central processing unit

3: road hopper 3 ': feeder

7: input liner 10: converter

20: sensing member 21: limit striker

22: elastic spring 30: through device

31: cylinder 40: fast pipe

41: connecting plate 42: appearance

43: guide 44: through tube

45: incision 46: support piece

Hereinafter, with reference to the accompanying drawings, the auxiliary material input pipe penetrating device of the converter of the present invention will be described in detail as follows.

Figure 5 is a configuration diagram showing the installation state of the sub-material input pipe penetrating device of the present invention, the feeder (3 ') for controlling the supply of the sub-material to the hearth hopper (3) installed on the upper side of the converter 10 is provided, At least one sensing member 20 is provided on the upper and lower sides of the input liner 7 connected to the feeder 3 ′, respectively, so as to sense the passage of subsidiary materials.

Each sensing member 20 is composed of a limit striker 21 which performs contact operation when the contact of the limit is separated by the tension of the elastic spring 22 while an external pressure of the sub-material is applied (see FIG. 8). The sensing member 20 of the side is connected to the solenoid 32 for operating the cylinder 31 for driving the penetrating device 30 for releasing the blockage of the pipe via the central processing unit 2, but the sensing member 20 of the upper side. Is connected to the feeder 3 'of the hearth hopper 3 via the central processing unit 2).

6 and 7 are separated perspective views showing the penetrating device of the present invention, and a perspective view of the coupling state thereof, wherein the penetrating device 30 is connected to maintain a proper gap G on the outside of the fast pipe 40 through which the sub-material passes. The exterior 42 connected by the plate 41 is formed coaxially, and the guide hole 43 is formed in the predetermined position of the exterior 42 so that it may be located symmetrically.

The gap G provided between the rapid pipe 40 and the exterior 42 is provided with a cutout 45 at a position corresponding to the connecting plate 41 to operate by the cylinder 31 and to act as a piston. One through tube 44 is coupled, and a support piece 46 is formed on the outer circumferential surface of the through tube 44 to be connected to the cylinder 31 through the guide hole 43 of the exterior 42.

Therefore, in the present invention as described above, clogging may occur at the lower end of the input liner in a process in which the sub-material 10 supplied to the hearth hopper 3 is introduced into the furnace of the converter 1 through the input liner 7. In this case, the secondary raw material that has not been introduced into the converter is accumulated from the lower end of the inclined liner to apply pressure on the conduit, whereby the limit striker 21 of the sensing member 20 protruding into the conduit is elastic spring 22. The contact is made while contracting.

The detection signal input to the sensing member 20 by the contact operation of the limit striker 21 sends an operation signal to the cylinder 31 driving the penetrating device 30 through the central processing unit 2, By the driving of the cylinder 31, the through pipe 44 of the penetrating device 30 acts as a piston in the gap G between the fast pipe 40 and the outer surface 42 outside thereof.

Therefore, the clogging portion penetrates as the impact pipe 40 and the outer shell 42 and the gap therebetween are removed by the sliding action of the through tube 44, and the attachments such as now attached thereto are removed.

On the other hand, the limit striker is operated as described above when the sub-materials to the sensing member 20 installed on the upper side in the process of the sub-material is continuously added to the input liner 7 in the state that the input port is blocked. As the detection signal is sent to the central processing unit 2 by the operation of the feeder, in this case, the feeder 3 'of the hearth hopper 3 containing the subsidiary material is operated regardless of the command sent from the input device 1. By stopping it, the filling of the input liner is minimized.

According to such a subsidiary material input pipe penetrating device of the present invention, as the input of the subsidiary material introduced into the furnace in the steelmaking process is smoothly introduced without any obstacles, the productivity of the converter is secured by improving the productivity of the converter. Of course, it is possible to find out the impediment of input of raw materials at an early stage, and to improve the quality of molten steel by minimizing the deterioration factors of the quality of molten steel in the emergency situation of subsidiary materials input at the worksite by utilizing appropriate alternative means of workers according to the working conditions. It can contribute to the effect.

Claims (1)

In the furnace 10, which is a steelmaking process, in order to control the molten steel temperature and the composition of the furnace, the raw material FLUX is introduced into the furnace through the feeder 3 'and the feeding liner 7 of the hearth hopper 3. , The sensing member 20, which is installed on the upper and lower sides of the input liner 7, is composed of the limit striker 21 which makes contact operation when the contact of the limit is separated by the tension of the elastic spring 22, while the external pressure of the sub-material is applied. And a penetrating device (30) operated by the cylinder (31) receiving the detection signal of the sensing member (20) and allowing the blockage of the input liner (7) to penetrate, and provided in the penetrating device (30). The exterior 42 formed coaxially to be connected by one connecting plate 41 to maintain the proper gap G on the outside of the guide 40, and the guide hole formed to be symmetrically located at a predetermined position of the exterior 42 And a through tube 44 having a cutout 45 at a position corresponding to the connecting plate 41 to be coupled to the gap G, and formed on an outer circumferential surface of the through tube 44. Characterized in that the configuration including a support piece 46 connected to the cylinder 31 through the guide hole 43 of (42) Injection pipe through the converter apparatus additives.