KR101351480B1 - Nozzle stopper for tuyere - Google Patents

Abstract

The present invention relates to a nozzle stopper for a winnowing machine which can prevent the bending of a winnowing machine for introducing hot air into a blast furnace. The nozzle stopper for a winnowing machine comprises: a blade buffering device fixed on both sides of a plate of the nozzle stopper for a winnowing machine to reinforce the rigidity of the plate; a bolt-shaped stopper installed under the end opposite to one end where the nozzle stopper for a winnowing machine is in contact with a winnowing machine to return to the center when the winnowing machine is dropped downward; and a connection part formed on the bottom of the opposite end of the nozzle stopper for a winnowing machine to connect the nozzle stopper for a winnowing machine and the bolt-shaped stopper.

Description

Blowhole nozzle stopper {Nozzle stopper for Tuyere}

The present invention relates to a blast furnace nozzle stopper of the blast furnace for preventing curved hands generated in the blast furnace by the attachment in the furnace falling from the top of the blast furnace.

The blast furnace, which produces cast iron from iron ore in the steel mill, is constructed of iron shells and lead ducts.

Daegong-gu refers to a cooling device installed to protect the shells and fire retardant outside the air ducts. It is a facility that blows hot air at about 1200 ° C from the outside of the blast furnace to the inside of the blast furnace. do. An average of 36 to 40 pieces are formed in the circumferential direction of the blast furnace, and the material is made of copper (Cu) having good thermal conductivity. In addition, the high-pressure water is used to cool the tuyere so as not to overheat.

1A and 1B are sectional views of a conventional blast furnace periphery and a blast furnace and a vent formed on the blast furnace wall surface.

As can be seen in the drawing, the blast furnace 100 has an inner wall formed of the soft breeze 10 and the outer circumference of the blast furnace 20 is surrounded by. The blast furnace 30 is formed in a certain portion of the blast furnace to form a vent hole 40 at the tip to allow the hot air of about 1200 ℃ flow into the furnace. A blow pipe 50 is connected to the rear end of the tuyere so that hot air supplied from the outside is introduced into the furnace through the tuyere. The blow pipe 50 is attached to the air outlet water supply and drain pipe 60 to prevent the air outlet from overheating through the cooling water.

However, the coke 70 is attached to the furnace wall due to changes in conditions such as excessive center flow operation in the furnace, and the attachment phenomenon may be caused by pressing or impacting the tip of the tuyere while the attachment is dropped. If the windball curve is severe due to the depressing phenomenon or the injury to the air vents, the coolant temperature may increase and the air vents may be broken, so that the air is kept for replacement. As a result, the production of cast iron is reduced, the unstable oil is unstable, and the cost of the cast iron is increased due to the shortening of the number of days of use of the tuyere, and the cost of replacement is high.

In order to compensate for such a problem, a tuyere nozzle stopper was installed to serve as a support to prevent windball fluctuations, but when the support is too weak and the yellowing is unstable, the tufts are bent due to the furnace wall attachment coming down. Frequently, there are cases that lead to a sensation or a shelter.

In addition, the relatively weak plate portion of the tuyere nozzle stopper may be bent by the furnace wall attachment coming down from the top of the furnace wall, and hot air may leak between the tuyere and the tuyere. Can lead to leeks.

It is an object of the present invention to provide a vane cushioning device in the weak plate portion of the tuyere nozzle stopper to prevent curvature of tuyere.

Still another object of the present invention is to prevent the curve of the air duct because it is installed so as not to exceed the curve of the air duct by additionally installing a blow nozzle nozzle stopper.

Still another object of the present invention is to attach the bolt-shaped stopper to the joint surface of the tuyere nozzle stopper to rebolt the inserted nut so as to return the tuyere that sags downward to the center to prevent tuyere.

According to one embodiment of the present invention, in the tuyere nozzle stopper for preventing curved hands from occurring in the tuyere inflowing hot air into the blast furnace, it is fixed along the shape of the side surface on both sides of the plate of the tuyere nozzle stopper Wing buffer to reinforce the rigidity of the plate; A bolt-shaped stopper installed at a lower portion of the opposite end portion of the tuyere nozzle stopper that contacts the tuyere to recover to the center when the tuyere sags downward; And a connection portion formed at the opposite end of the tuyere nozzle stopper to connect the tuyere nozzle stopper and the bolt-type stopper.

Preferably, the vane buffer is characterized in that the same material as the tuyere nozzle stopper.

Preferably, the bolt-type stopper has a cotter pin hole formed at one end thereof and the other end includes a bolt fixed to the outer surface of the blast furnace, a plurality of nuts fastened to the bolt and a cotter pin inserted into the cotter pin hole. It is characterized by.

Preferably, the connection portion formed at the opposite end end of the tuyere nozzle stopper is characterized in that it comprises a threaded hole so that the bolt is fixed through the middle of the longitudinal direction.

Preferably, one end of the bolt fixed to the hole is fixed in contact with the outer wall of the blast furnace, the other end is fastened to the first and second nuts, characterized in that the cotter pin hole is inserted into the cotter pin hole of the rear end .

Preferably, as the first nut rotates, the tuyere nozzle stopper is shifted toward the tuyere, and the second nut is disposed in contact with the first nut at the rear end of the first nut, thereby positioning the position of the first nut. It is characterized in that the fixing.

By practicing the present invention, it is possible to prevent the curve of the tuyere to prevent the idle air in advance to improve the productivity and reduce the cost. In addition, stable operation is possible by fundamentally preventing the idle air and the wind. In addition, it is possible to prevent accidents of large-scale equipment such as wind tunnels.

1A and 1B are sectional views of a conventional blast furnace periphery and a blast furnace and a vent formed on the blast furnace wall surface.
2A and 2B are views showing the structure of the conventional blowhole nozzle stopper and the shape in which the blowhole nozzle stopper is provided at the hot air inlet of the blast furnace.
3 is a view showing the structure of the tuyere nozzle stopper is installed in accordance with the present invention.
Figure 4 is a view showing the nozzle nozzle stopper coupled to the bolt-shaped stopper according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. The accompanying drawings are intended to aid the understanding of the invention and should not be construed as limiting the invention thereto. It should be understood that the invention should be limited only by the claims.

2A and 2B are views showing the structure of the conventional blowhole nozzle stopper and the shape in which the blowhole nozzle stopper is provided at the hot air inlet of the blast furnace.

2A shows a top and side view of the tuyere nozzle stopper. As can be seen in the figure, the conventional tuyere nozzle stopper 200 is formed in a long wedge shape. As shown in the figure, the hook 220 is formed at the left end, and is used to attach the tuyere nozzle stopper 200 to the tuyere. The tuyere nozzle stopper has a shape that becomes thinner from left to right, and is easily inserted below the blow pipe (see Fig. 2B). For this reason, the tuft nozzle stopper has a weak plate portion 210 in structure. When the attachment attached to the upper part of the tuyere falls and presses the tuyere, the tuyere may be struck downward, thereby causing the weak plate portion 210 of the tuyere nozzle stopper to bend or break. Therefore, when the weak plate portion 210 of the tuyere nozzle stopper is reinforced, it is possible to prevent a large part from being bent or broken.

3 is a view showing the structure of the tuyere nozzle stopper is installed in accordance with the present invention a wing shock absorber.

Referring to the drawings, the wing buffer device 215 is attached to both sides of the plane of the tuyere nozzle stopper 200 according to the present invention, such as by welding, the tuyere nozzle stopper 200 when the tuyere is pressured from the top of the furnace It will support to prevent it from bending down or breaking easily. The wing buffer 215 may be formed of a material such as a tuyere nozzle stopper, or may use another metal of higher strength. The wing buffer 215 may be installed in such a way as to enclose the weak plate portion 210 of the tuyere nozzle stopper, but if so installed, the plate portion 210 becomes too thick as a whole and detaches below the blower pipe. This can be difficult to make easily. Therefore, the wing buffer 215 is preferably formed only on both sides of the plate.

On the other hand, if the attachments falling from the upper furnace wall of the tuyere due to the instability of the blast is severely pressed by the tip of the tuyere or worsened by the impact, it may be difficult to withstand one tuyere nozzle stopper. At this time, if the addition of the tuyere nozzle stopper, for example, by adding two more to install a total of three, it is possible to further strengthen the role of the support so as not to exceed the tuyere curve limit.

Figure 4 is a view showing the nozzle nozzle stopper coupled to the bolt-shaped stopper according to the present invention.

As can be seen in the figure, the bolt-shaped stopper 300 is additionally mounted and used in the tuyere nozzle apparatus according to the present invention, which forms another feature of the present invention. That is, the bolt-type stopper 300 is installed at the lower portion holding the tuyere nozzle stopper 200, and the curved tuyere is returned to its center by the force generated by the bolt-type stopper.

The bolt-type stopper 300 according to the present invention inserts the bolt 310 having no head on the fastening hole 250 of the bolt-type stopper formed in the connection portion 270 of the tuyere nozzle stopper 200, and then fastens. Two nuts 320 are coupled to the rear of the inlet, that is, the first nut 321 and the second nut 322 are coupled to each other. The first nut 321 serves to raise the downward curved tuyere to the center. That is, when the first nut 321 is tightened, the connection part 270 of the tuyere nozzle stopper is advanced to return the downwardly curved tuyere to the center.

Subsequently, the second nut is tightened to contact and fix the first nut. In this way, the second nut serves as a kind of support to keep the first nut in its current position without loosening. Thus, even if the hot air in the furnace leaks and the first nut is burned out, the secondary accident is prevented.

Subsequently, by inserting and fixing the cotter pin in the cotter pin hole 340 formed at the rear end of the bolt, the bolt-type stopper is tightly fixed. 330 will ensure the support role.

When the tuyere is curved, the process of recovery by the tuyere nozzle stopper of the present invention will be described.

That is, when the first nut is slowly tightened to the rear end of the bolt 310 of the bolt-shaped stopper installed at the lower part of the tuyere nozzle stopper with an impact wrench (not shown), the connection part 270 of the tuyere nozzle stopper is advanced, and the tuyere is moved to the center. You will be gradually restored. When the return is complete and the zero adjustment is completed, the second nut is coupled to the rear of the first nut so that the first nut does not loosen from the bolt. A cotter pin is installed at the rear to prevent the entire tuyere from shaking.

The fluctuations of the tufts occur from the furnace body, which is not equipped with a wide cooling panel and a cigar cooling panel, which are cooling devices inserted in the furnace wall to reduce the heat load of the lead on the upper part of the furnace body, or the stave is damaged. If all are not burned, the semi-melt from the top gradually approaches the top of the tuyere and burns the attachment at the top. At this time, due to the contact between the indentation pressure and the semi-melt coming down from the top, the tuyere may not hold much, can easily lead to tuyere damage or curve. However, according to the present invention, a vane shock absorber is provided in the plate portion of the tuyere nozzle stopper, and a bolt-shaped stopper is provided at the bottom to prevent occurrence of tuyere curvature.

The embodiment of the tuyere nozzle stopper according to the present invention described above is merely illustrative, and those skilled in the art to which the present invention pertains that various modifications and equivalent other embodiments are possible. I can see it well. It is therefore to be understood that the invention is not limited solely to the form set forth in the foregoing description. Therefore, the true scope of the present invention should be defined only by the technical idea of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

100: blast furnace 10: yeonwa
20: Blast Furnace 30: Daegonggu
40: blowhole 50: blow pipe
70: coke 200: blowhole nozzle stopper
210: plate part 215: wing type shock absorber
220: Hook 250: Hole for fastening the bolt stopper
270: connection portion of the blowhole nozzle stopper 300: bolted stopper
310: bolt 320: nut
321: first nut 322: second nut
330: cotter pin 340: cotter pin hole

Claims (6)

In the tuyere nozzle stopper for preventing curved hands from occurring in the tuyere inflowing hot air into the blast furnace,
Wing buffer devices fixed to both sides of the plate of the tuyere nozzle stopper along the shape of the side to reinforce the rigidity of the plate;
A bolt-shaped stopper installed at a lower portion of the opposite end portion of the tuyere nozzle stopper that contacts the tuyere to recover to the center when the tuyere sags downward; And
And a connecting portion formed at an end of the opposite end of the tuyere nozzle stopper to connect the tuyere nozzle stopper and the bolt-shaped stopper. The method of claim 1,
The vane nozzle stopper is a tuyere nozzle stopper, characterized in that the same material as the tuyere nozzle stopper. The method of claim 1,
The bolt-type stopper has a cotter pin hole formed at one end thereof, and the other end thereof includes a bolt fixed to the outer surface of the blast furnace, a plurality of nuts fastened to the bolt, and a cotter pin inserted into the cotter pin hole. Funnel nozzle stopper. The method of claim 1,
The connecting part comprises a hole formed with a screw thread so that the bolt penetrates and is installed in the middle of the longitudinal direction. 5. The method of claim 4,
One end of the bolt fixed to the hole is fixed to the outer wall of the blast furnace, the other end of the first and second nuts are fastened in turn, the cotter pin hole of the cotter pin is characterized in that the cotter pin is inserted into the stopper. The method of claim 5,
As the first nut rotates, the tuyere nozzle stopper is advanced toward the tuyere, and the second nut is disposed in contact with the first nut at the rear end of the first nut, thereby fixing the position of the first nut. Blow nozzle nozzle stopper.

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