KR101279059B1 - Device for protecting heat loss of runner in furnace - Google Patents

Abstract

At least one guide rail installed on the roadway and extending in the width direction of the large tap water and disposed along the large tap water so as to minimize a temperature drop of the melt in the large tap water, and moved along the guide rail To cover and block the selectively and provide a blast furnace heat loss prevention apparatus comprising at least one cover member of a planar structure extending linearly between both side ends in the width direction.

Description

DEEPICE FOR PROTECTING HEAT LOSS OF RUNNER IN FURNACE}

The present invention relates to a large degree of blast furnace. More specifically, the present invention relates to a large-scale hot water loss prevention apparatus for minimizing the melt temperature drop in the large-scale water.

In general, the blast furnace operation charges iron ore and coke from the upper part of the furnace, and blows high temperature hot air sent from the hot blast furnace equipment from the bottom to melt and reduce the iron ore as heat to produce the molten iron.

Waste water generated in the blast furnace is discharged through the outlet formed in the side of the blast furnace. The waste water discharged from the exit is placed in a mixed truck (TLC) after passing through a large bath on the blast furnace.

The large hot water is a main hot water that is separated from molten iron and slag while the melt flowing out of the blast furnace moves, and the hot melt is released into the atmosphere and the temperature starts to drop.

In blast furnace operation, molten iron temperature management has a very important meaning. Melting temperature control is essential for the subsequent steelmaking smelting process. The temperature loss of the molten iron requires an additional heat source, which is an additional cost.

Therefore, in the related art, a splash cover is installed on the upper side of a large hot water supply to block the melt from the outside to prevent radiant heat loss of the melt. In addition, a dust collector is provided and the melt sucks and scatters dust when the large water is introduced.

However, the conventional structure has a problem in that the splash cover is spaced apart from the melt of the large hot water by a considerable distance, and the radiant heat loss due to the temperature difference between the melt and the splash cover inner surface is large. In addition, due to the suction pressure of the dust collector, convection occurs in the space inside the splash cover, and the heat loss is further increased.

Therefore, in the case of the structure using a conventional splash cover, there is a problem that the heat loss is large enough to reach the 50 ~ 60 ℃ difference between the melt temperature in the starter side melt temperature and the skimmer of the large hot water.

Accordingly, the apparatus provides a heat loss preventing apparatus of a blast furnace that is capable of minimizing the temperature drop of the melt in the large bath.

To this end, the device is installed on the road and extends in the width direction of the large tap road and at least one guide rail disposed along the large tap road, and moved along the guide rail to selectively cover and block the top of the large tap road. At least one cover member of a planar structure extending linearly between both side ends in the width direction may be included.

The cover member may include a frame forming a skeleton, and a plurality of refractory tiles attached to an outer surface of the frame.

The apparatus may further include a blocking unit installed at the side end of the cover member to block a gap between the cover member and the melt in the large bath.

The blocking unit may include a shaft member installed at the cover member side end, and a blocking member rotatably installed at the shaft member and lowered downward to the cover member to block between the cover member and the melt of the large bath.

The blocking unit may be installed at a side of the outlet side of the cover member disposed on the outlet side of the blast furnace of the plurality of cover members.

The blocking member may include a frame forming a skeleton and a plurality of refractory tiles attached to an outer surface of the frame.

The apparatus may further include a moving part for moving the cover member along the guide rail.

The moving part may include a driving cylinder installed on the road and disposed in the width direction of the large bath and connected to the tip of the cover member.

According to the present embodiment as described above, by improving the cover structure covering the large hot water island, it is possible to minimize the radiant heat loss of the melt to reduce the temperature drop of the molten iron.

In addition, it is possible to reduce the temperature drop of the molten iron by minimizing convective heat loss caused by the dust collector.

In addition, it is possible to more easily perform the heat management and the water management of the large tap water.

1 is a schematic perspective view showing the apparatus for preventing heat loss of a large hot water in accordance with the present embodiment.
Figure 2 is a perspective view showing in more detail a part of the configuration of the apparatus for preventing large heat loss according to the present embodiment.
3 is a side cross-sectional view of the apparatus for preventing large heat loss in accordance with the present embodiment.
4 is a sectional front view of the apparatus for preventing large heat loss according to the present embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Wherever possible, the same or similar parts are denoted using the same reference numerals in the drawings.

All terms including technical and scientific terms used herein have the same meaning as commonly understood by those of ordinary skill in the art to which the present invention belongs. Predefined terms are further interpreted as having a meaning consistent with the relevant technical literature and the present disclosure, and are not to be construed as ideal or very formal meanings unless defined otherwise.

1 shows a heat loss preventing apparatus installed in a large bath according to the present embodiment, FIG. 2 shows a partial configuration of the apparatus in more detail, and FIGS. 3 and 4 show a cross-sectional structure of the apparatus. It is shown.

Referring to the drawings, in the blast furnace 100, as the coke and pulverized coal is burned, a reducing gas is generated and reacts with iron ore, whereby a melt made of molten iron and slag is produced. The produced melt is discharged to the large bathway 130 through the outlet 110 of the blast furnace 100. The large bath 130 is formed in the form of a waterway on the hearth of the blast furnace 100, the melt is separated into the molten iron and slag by the specific gravity difference while flowing along the large bath 130. The molten iron separated from the large bathway 130 is sent to the crossroad car and the slag is sent to a dry pit along the slag furnace 140 connected to the large bathway 130 to be processed.

Here, the apparatus is configured to cover the upper end of the large waterway 130 to prevent the melt temperature drop in the large waterway 130.

To this end, the apparatus is installed on the road and extends in the width direction of the large bathway 130, and at least one guide rail 10 disposed along the large bathway 130, and moved along the guide rail 10 to the above. At least one cover member 20 for selectively covering and covering the upper end of the large bath 130 is included.

In the present embodiment, the cover member 20 has a planar structure extending linearly between both side ends in the width direction of the large bath 130.

As the cover member 20, which is a flat structure, covers the upper end of the large bathway 130, the large bathway 130 is blocked from the outside in a state in which the space between the melt and the cover member 20 is minimized. Therefore, convective heat loss and radiant heat loss in the space between the large bath 130 and the cover member 20 can be minimized.

A plurality of the cover member 20 is disposed side by side along the large bath 130, and the guide rail 10 is also disposed at a position corresponding to each cover member 20 to move the bottom of the cover member 20 Possibly supported.

As shown in FIG. 2, the guide rail 10 has a structure in which a plurality of rotating rolls 12 are provided at intervals along the longitudinal direction. The cover member 20 is more smoothly moved in the width direction of the spout 130 by the rotation roll 12 is freely rotated.

In addition, the apparatus further includes a moving part for moving the cover member 20 along the guide rail (10). In this embodiment, the moving part includes a driving cylinder 30 installed on the road and disposed in the width direction of the large bathway 130 and connected to the tip of the cover member 20.

The driving cylinder 30 is installed on each of the plurality of cover members 20 to drive the cover members 20 individually, or is provided with one drive cylinder 30 to move the plurality of cover members 20 together. You can.

Accordingly, when the driving cylinder 30 is stretched and operated, the cover member 20 connected to the tip of the piston rod of the driving cylinder 30 moves along the guide rail 10 in the width direction of the large bath 130.

The cover member 20 is to block the upper end of the large bath 130, as shown in Figure 2, the frame 22 of the frame forming a skeleton and attached to the frame 22 to form an outer surface A plurality of refractory tiles 24 are included.

Since the cover member 20 is exposed to the high heat generated from the melt in the large bath 130, it should be able to withstand high heat sufficiently. Accordingly, the refractory tile 24 made of a refractory material is closely attached to the outer surface of the cover member 20 so that there is no gap. The refractory tile 24 may be attached to the entire surface including the lower surface of the frame 22, or may be attached only to the lower surface directly facing the melt, and is not particularly limited in terms of its attachment surface.

In the present embodiment, since the refractory tile 24 of the cover member 20 is close to the melt, it may be made of an alumina-based refractory material unlike the refractory used in the conventional splash cover. The material of the refractory tile 24 is not limited thereto, and any material can be used as long as it can withstand a temperature of about 1400 ° C.

By attaching the alumina refractory tile 24 to the cover member 20 as described above, damage of the cover member 20 can be minimized even if the cover member 20 and the melt of the large bath 130 are close.

On the other hand, the apparatus is installed on the side end of the cover member 20 disposed closest to the exit port 110 side of the blast furnace 100 of the plurality of cover member 20 is the cover member 20 and large bath 130 It further comprises a block for blocking the gap between the melt in).

The blocking portion is rotatably installed on the shaft member 42 and the shaft member 42 which is installed at the side of the cover member 20, and is lowered in a vertical direction to the cover member 20 so that the cover member 20 and the large bath ( Blocking member 40 for blocking between the melt of 130.

The shaft member 42 is a pair of two to support the both ends of the blocking member 40 rotatably. The cover member 20 is coupled to the shaft member 42 and rotated 270 degrees while being horizontally placed on the top surface of the cover member 20 to be lowered in a direction perpendicular to the cover member 20. The blocking member 40 is raised to the upper surface of the cover member 20 when moving the cover member 20 to prevent interference due to the movement, if necessary, rotated from the cover member 20 is lowered toward the bottom of the large bath 130 You lose.

Therefore, the blocking member 40 is lowered from the cover member 20 toward the large bathway 130 to block the gap between the cover member 20 and the melt in the large bathway 130.

The blocking member 40 is formed to have a length corresponding to the inner width of the large bath 130, and when the cover member 20 is lowered from the side end, the blocking member 40 has a size such that the lower end does not come into contact with the melt.

Since the blocking member 40 is in contact with the melt of a high heat like the cover member 20, it must be able to withstand high heat sufficiently. To this end, the blocking member 40 also includes a frame 44 forming a skeleton, and a plurality of refractory tiles 46 attached to the outer surface of the frame 44.

As mentioned above, the refractory tile 46 is not particularly limited in terms of its material. In the present embodiment, the refractory tile 46 is made of alumina-based refractory material.

Hereinafter, an operation process of the heat loss preventing apparatus of the present embodiment having the above structure will be described with reference to FIGS. 3 and 4.

When the driving cylinder 30 is extended, the cover member 20 connected to the piston rod of the driving cylinder 30 is moved along the guide rail 10. The cover member 20 which is moved along the guide rail 10 passes through the upper end of the large tap water 130 in the width direction to cover the upper tap water 130.

When the cover member 20 is completely moved to completely cover the upper bath 130, the blocking member 40 installed at the side end of the cover member 20 disposed at the outlet 110 of the blast furnace 100 is rotated.

When the blocking member 40 is rotated and lowered down, as shown in FIG. 3, the blocking member 40 blocks the cover member 20 and the melt in the large bath 130.

The large waterway 130 is covered by a cover member 20 of a flat structure passing horizontally over the large waterway 130 is blocked from the outside, the distance between the cover member 20 and the melt in the large waterway 130 is Minimum. Therefore, the heat loss through the space between the melt and the lid member 20 can be minimized.

In addition, the gap between the cover member 20 side end and the melt of the large bath 130 is blocked by the blocking member (40). In this way, the occurrence of convection in the internal space of the large bath 130 covered by the cover member 20 may be reduced, and heat loss due to convection may be minimized.

While the illustrative embodiments of the present invention have been shown and described, various modifications and alternative embodiments may be made by those skilled in the art. Such variations and other embodiments will be considered and included in the appended claims, all without departing from the true spirit and scope of the invention.

10: guide rail 12: rotary roll
20: cover member 22,44: frame
24, 46: refractory tile 30: driving cylinder
40: blocking member 42: shaft member

Claims (10)

At least one guide rail installed on the road and extending in the width direction of the large waterway and disposed along the large waterway, and moved along the guide rail to selectively cover and block the upper surface of the large waterway, and both sides of the large waterway in the width direction At least one cover member of the planar structure extending linearly between,
The cover member is a blast furnace heat loss prevention apparatus comprising a frame forming a skeleton and a plurality of refractory tiles attached to the outer surface of the frame. delete The method of claim 1,
The refractory tile is heat loss prevention device of the blast furnace made of alumina-based refractory. The method of claim 1,
An apparatus for preventing heat loss of a blast furnace further comprising a moving unit for moving the cover member along the guide rail. The method of claim 4, wherein
The moving part is installed on the road and the large-scale hot water prevention apparatus of the blast furnace including a driving cylinder which is disposed in the widthwise direction and connected to the tip of the cover member. 6. The method according to any one of claims 1 to 5,
It is installed on the side end of the cover member heat dissipation prevention device of the blast furnace of the blast furnace further comprises a blocking portion for blocking the gap between the cover member and the melt in the water. The method according to claim 6,
The cut-off portion of the blast furnace including a shaft member installed at the cover member side end, a blocking member rotatably installed on the shaft member and lowered to the cover member to block the melt between the cover member and the melt of the large bath. Loss prevention device. The method of claim 7, wherein
The cut-off portion of the blast furnace hot water loss prevention device is installed at the side end of the outlet of the cover member disposed on the outlet side of the blast furnace of the plurality of cover members. The method of claim 7, wherein
The blocking member is a blast furnace heat loss prevention apparatus comprising a frame constituting the skeleton and a plurality of refractory tiles attached to the outer surface of the frame. The method of claim 9,
The refractory tile is heat loss prevention device of the blast furnace made of alumina-based refractory.

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