KR20020031208A - Disc for removing heat from dust recycling system of corex - Google Patents

Abstract

PURPOSE: A disc for radiating heat from a dust recovery line of Corex is provided which prevents facility trouble, shortens life cycle and prevents operation obstacles by installing castable with superior adiabatic performance inside the heat radiation disc, thereby preventing thermal shock from transferring of dust of a high temperature. CONSTITUTION: In a disc gate device(114) equipped with a dust recycling system of a Corex facility, a Corex radiation disc is constructed so that a high temperature electric heat is cut off from a dust transfer channel(150) by installing a castable(15) with superior adiabatic performance inside a hollow casing(10), wherein loop metal gaskets(32a,32b) are mounted on upper and lower surfaces of the casing(10) so that sealing is made between the casing(10) and a frame on which the casing(10) is mounted, and wherein a separation plate(12) dividing into two parts is mounted on the inner part of the casing(10), the dust transfer channel(150) is formed at the center of one side of the first space, the castable(15) is filled in the inside of the casing(10) so as to encircle the dust transfer channel(150), and the castable(15) is also filled in the other side of the second space.

Description

Heat dissipation disk of COREX dust recovery line {DISC FOR REMOVING HEAT FROM DUST RECYCLING SYSTEM OF COREX}

The present invention relates to a heat dissipation disk provided in a dust recycling system of a COREX facility, and more particularly, a built-in castable with excellent thermal insulation performance prevents thermal shock during operation from high temperature dust transportation, thereby preventing equipment failure and lifespan. The present invention relates to a heat dissipation disk of a corex dust recovery line improved to prevent shortening and operation failure.

In general, the dust recycling system 100 of Korex is provided with a cyclone (Cyclone) (110) for separating the dust from the hot gas, as shown in Figure 1, the lower side of the dust blocking valve for opening and closing the dust ( 112 and a corex disk gate 114, an upper dust bin 116 is located on the lower side of the gate 114, and another corex disk gate 118 on the lower side.

The lower dust bin 120 is positioned at the lower side thereof, and the shutoff valve 122 is sequentially provided to separate the dust separated from the hot gas at the cyclone 110 by the dust burner of the Korex facility 130. Resupply to 124 for recycling.

In such a dust recycling system 100, the disk gate device 114 is installed in the conduit to control the transport amount of dust, the high temperature of the dust is passed through the inside of the facility, it is maintained at a high temperature.

2 and 3 illustrate a heat radiation disk 140 according to the prior art. The heat dissipation disk 140 is mounted on the inner frame 114a of the disk gate device 114 and has a spiral coolant flow path 142 therein, and the coolant supplied through the plurality of coolant inlet pipes 144 is While passing through the helical flow path 142, the plurality of cooling water discharge pipes 146 exit. However, the conventional heat dissipation disk 114 is designed and manufactured in consideration of sufficient durability against high heat as a heat-resistant steel sheet, but during operation, a dust transport path having a high temperature of about 850 ° C. is formed at the center of the heat dissipation disk 140. Since the flow path is opened or blocked to move through the 150, the fatigue due to the thermal shock is increased, and the iron part 140a around the inner flow path is cracked to frequently cause equipment accidents in which the coolant flows out. .

That is, the conventional heat dissipation disk 140 has a dust conveying flow path 150 formed at the center, and has a structure in which cooling water flows, and the blocking plate 160 located at the lower side thereof rotates to allow the flow path 150 to rotate. It can be activated to selectively block or open. Therefore, the dust transfer path 150 is a weak point that is always exposed to high temperature dust and subjected to thermal shock. However, the heat dissipation disk 140 of the related art was weak in thermal shock due to its weakness in ductility and thermal conductivity, and thus, of the metal shell 140a of the dust transfer path 150 of the heat dissipation disk 140. When the coolant is leaked due to the crack, the coolant is penetrated into the dust recycling system 100, as well as having a problem such as an operation stop due to the deformation of the heat dissipation disk 140 and the normal function of the conduit.

In addition, the conventional heat dissipation disk 140 has an O-ring 148 mounted on the outer circumferential side of the upper and lower surfaces, respectively, so that the disk gate device is disposed between the upper and lower surfaces of the heat dissipation disk 140 and the inner frame 114a of the disk gate device 114. (114) It is intended to block the outflow of gas and dust to the outside. However, the O-ring 148 is vulnerable to high temperature and often does not maintain its function, so that gas and dust leaks out of the disk gate device 114 to contaminate the surrounding environment and impair the safety of the worker.

The present invention is to solve the conventional problems as described above, its purpose is to embed a castable with excellent thermal insulation performance to prevent the thermal shock of rapid thermal change that is transferred from the dust transported during operation dust is transported The present invention provides a cooling device for a Corex heat-dissipating disk that is improved to prevent cracks in the steel parts and to allow normal operation, thereby preventing shortening of life and operational disturbances.

1 is a block diagram showing a dust recycling system of a typical Korex facility;

Figure 2 is a cutaway plan view of a corex heat dissipation disk according to the prior art;

3 is a cross-sectional view in which a heat dissipation disk according to the prior art is mounted on a corex disk gate;

Figure 4 is an exploded perspective view of a portion of a corex heat radiation disk according to the present invention;

5 is a cutaway plan view of a Corex heat radiation disk according to the present invention;

6 is a cross-sectional view taken along the line A-A of FIG.

7 is a cross-sectional view of the cooling apparatus according to the present invention mounted on a dust recycling system of a Korex facility.

Explanation of symbols on the main parts of the drawings

10 ..... Casing 12 ..... Plate

15 ..... Castable 20,26 ... Castable inlet

22,28 ... Air outlet 32a, 32b .... Metal gasket

100 .... COREX Dust Recycling System

110 .... Cyclone 114 .... Disc Gate

116 ... upper dust bin 142 .... coolant flow path

144 ... Chilled water inlet 146 .... Chilled water outlet

150 ... dust transfer path

In order to achieve the above object, the present invention, in the heat dissipation disk of the disk gate device provided in the dust recycling system of the Corex facility, from the dust transfer path by embedding a castable with excellent thermal insulation inside the hollow casing By providing a corex heat radiation disk, characterized in that configured to block the high temperature heat transfer.

The present invention provides a heat dissipation disk according to claim 1, wherein annular metal gaskets are mounted on the upper and lower surfaces of the casing, respectively, to provide sealing between the casing and the frame on which the casing is mounted. All.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

As shown in FIGS. 4 to 6, the corex heat-dissipating disk 1 according to the present invention has a round disk-shaped casing 10, the casing 10 is made of a heat-resistant steel sheet, the space therein The diaphragm 12 which divides into 2 is mounted.

And, the casing 10 is configured to block the high temperature heat transfer from the dust transfer flow path 150 by embedding the castable 15 having excellent heat insulating performance in the hollow inside, for this purpose, the center The dust conveyance passage 150 is formed, and the castable 15 is filled inside the first space on one side to surround the dust transfer passage 150, and the castable 15 is formed as the other second space. It is filled.

On the other hand, the first space side is formed with a castable inlet 20 on one side, the other side is formed with an air outlet 22 for the smooth discharge of the internal air during injection of the castable 15, the castable The injection passage is formed to surround the dust transfer passage 150.

In addition, a castable injection hole 26 for injecting the castable 15 into the second space is provided on one side of the second space, and the other side of the second space is castable to the second space. (15) The air outlet 28 for discharging the air in the inner space to the outside during injection is formed.

On the other hand, the upper and lower surfaces of the casing 10, respectively, is provided with annular metal gaskets (32a, 32b) to form a seal between the frame (114a) on which the casing 10 is mounted, The outer diameter of the casing 10 is between the casing 10 and the frame 114a on which the casing 10 is mounted, as the outer diameter of the metal gaskets 32a and 32b approximately coincides with the outer diameter of the casing 10. It is pressed in place to seal the space therebetween. Therefore, dust or gas does not leak out of the disk gate device 114 from the flow path of the disk gate device 114 communicated with the dust transfer path 150.

When the heat dissipation disk 1 of the present invention configured as described above is to fill the heat insulating castable 15 in the casing 10, the castable 15 through the castable inlet 20, 26 ), The semi-solid adiabatic castable 15 is filled therein, and when the filling is completed and the castable 15 is partially discharged to the air outlet 22 and 28, the injection is stopped and a fixed time Neglect to cure.

In addition, the casing 10 filled with the heat insulating castable 15 inside is mounted on the inner frame 114a of the disc gate device 114. In this case, the upper and lower surfaces of the casing 10 are annular. Positioning and mounting the metal gaskets 32a and 32b effectively blocks the outflow of dust or gas from the inside of the disk gate device 114 to the outside through the space between the upper and lower surfaces of the casing 10 and the frame 114a. It becomes possible.

Such a heat dissipation disk 1 of the present invention, when the blocking plate 160 of the lower side is rotated to block the dust transfer flow path 150 formed in the center of the heat dissipation disk 1, through the disk gate device 114 Dust flow is prevented. However, when the blocking plate 160 is rotated to the side to open the dust conveyance passage 150, high temperature dust is transferred downward through the dust conveyance passage 150, and in this process, the high temperature is directed to the heat dissipation disk 1 side. Is heated. However, since the heat dissipation disk 1 of the present invention is filled with the heat insulating castable 15 therein, the rate at which the high temperature heat is transferred to another part of the disc gate device 114 becomes very low.

Therefore, the hot dust is transferred to the lower side without transferring the heat to the disk gate apparatus 114 side, and the disk gate apparatus 114 maintains smooth operation.

The heat dissipation disk 1 of the present invention is not able to block the high temperature heat that is transferred from the dust better than the conventional cooling method using the cooling water, but the heat insulating castable 15 filled in the casing 10. Due to the high heat can be effectively transferred to the outside by low heat conduction for a certain time, the disk gate device 114 equipped with the heat dissipation disk 1 of the present invention can achieve a stable operation for a considerable time In this case, the casing 10 is not cracked by forming a sudden temperature difference in the vicinity of the dust transport path 150 of the casing 10.

In addition, since the metal gaskets 32a and 32b are positioned on the upper and lower sides of the casing 10 to form a seal with the inner frame 114a of the disk gate device 114, deformation is prevented even by high temperature heat that is transferred. Thus, the gas and the dust inside the disk gate device 114 can be effectively sealed without release to the outside.

In addition, since there is no outflow of the cooling water as in the related art, it is possible to stably operate the equipment, and the inflow of the cooling water does not occur, thereby preventing equipment accidents.

As described above, according to the present invention, the casing 10 having a round disc shape and having a heat-resistant steel plate has a built-in castable 15 having excellent thermal insulation performance due to the high temperature transferred from dust transferred during operation. It is possible to prevent the thermal shock of a sudden thermal change to prevent cracks in the iron part (140a) to which dust is transported, and to enable the normal operation of the disk gate device 114 to improve equipment life shortening and operation failure Effect is obtained.

Claims (3)

In the heat-dissipating disk of the disk gate device 114 provided in the dust recycling system 100 of the Korex facility, the dust transport passage 150 by embedding a castable (15) having excellent heat insulating performance inside the hollow casing (10) Corex heat dissipation disk, characterized in that it is configured to block the high temperature heat transfer from). According to claim 1, wherein the upper and lower surfaces of the casing (10) are each equipped with annular metal gaskets (32a, 32b) is sealed between the frame (114a) on which the casing 10 is mounted Corex heat radiation disk. According to claim 1, wherein the casing (10) is mounted therein partition 12 for dividing the space therein, a dust transfer passage 150 is formed in the center of one side of the first space, the dust transfer passage ( 150 is filled with a castable (15) inside to surround, the other side of the second space, the castable (15) characterized in that the filling of the castable heat disk.