KR100868506B1 - Combustion device for oxygen in electro furnace - Google Patents

Abstract

An object of the present invention is to put the carbon powder heated into the electric furnace through the gas port ring to react with the unreacted oxygen to prevent the unreacted oxygen from escaping through the gas port ring to burn the unreacted oxygen in the furnace In providing a device.

The present invention is an electric furnace including a carbon preheating means for heating the powdered carbon using the high heat of the fume discharged from the electric furnace, and a carbon injection means for injecting the preheated powdered carbon into the electric furnace through a gas port ring It provides an unreacted oxygen combustion device.

Housing, Hopper, Carbon, Transfer Pipe, Distribution Pipe, Injection Hole

Description

Combustion device for oxygen in electro furnace

1 is a partially cutaway perspective view showing an electric furnace in which an unreacted oxygen combustion device according to the present invention is installed;

2 and 3 is a detailed view showing a part of the configuration of the unreacted oxygen combustion apparatus according to the present invention,

4 is an operating state diagram of the unreacted oxygen combustion apparatus according to the present invention.

Explanation of symbols on the main parts of the drawings

10: electric furnace 20: loop

30; Gas port ring 40: Elbow

50: duct 60: housing

61: hopper 62: supply pipe

63: transfer pipe 64: valve

65: driving cylinder 66: blocking plate

70: distribution pipe 71: injection hole

72: connection hole 73: gas pipe

The present invention relates to an electric furnace, and more particularly, to an unreacted oxygen combustion apparatus of an electric furnace that is capable of completely burning oxygen injected into an electric furnace to prevent oxygen from escaping through gas photoling of a loop. .

In general, an electric furnace refers to a furnace for heating and dissolving a metal or alloy using electricity. When a high voltage is applied to three electrodes vertically connected to an upper part of a loop of an electric furnace, high-temperature arc heat is generated to dissolve charged scraps in the electric furnace. Done. At this time, a gas port ring is installed on the roof to collect a large amount of waste gas, dust, and fume generated during the melting process of the scrap, and open gas elbows, sleeves, and open gas ducts are installed in succession to the gas port ring. Will be sent to the dust collector.

And the scrap is dissolved in the electric furnace and oxygen is blown from the time when the molten metal is formed. For this purpose, an oxygen lance for blowing oxygen is installed at one side of the lower part of the electric furnace, which is about 10N㎥ / steel-ton. This electricity is put into the furnace.

The reaction efficiency of oxygen introduced into the electric furnace is about 70% and the rest is discharged to the duct through the gas port ring.

However, in the conventional electric furnace, when unreacted oxygen escapes through the gas port ring as described above, the flying flame generated between the electrode and the scrap is sucked into the gas port ring and oxidized to a high temperature inside the gas port ring and the duct. There is a problem.

That is, as the unreacted oxygen and the flying flame are sucked together toward the duct, the flying flame reacts with the oxygen rapidly in the gas port ring and the duct to rapidly oxidize and generate a lot of heat. It is broken at high temperatures.

In particular, such a phenomenon occurs frequently in the region where the cooling tube is formed, which causes the cooling tube breakage, and the cooling water leaks, which causes additional problems.

In addition, since the scrap of the portion where the gas port ring is installed in the conventional electric furnace does not have a heat source that is relatively secured compared to the scrap of the other place, the phenomenon of attaching to the wall of the electric furnace occurs frequently, which causes the non-uniformity of the molten steel component of the electric furnace. Becomes

Accordingly, the present invention has been made to solve the above-mentioned problems, by putting the carbon powder heated into the electric furnace through the gas port ring to react with the unreacted oxygen to escape the unreacted oxygen through the gas port ring It is an object of the present invention to provide an unreacted oxygen combustion apparatus of an electric furnace that can be prevented.

In addition, another object of the present invention is to provide an unreacted oxygen combustion apparatus of an electric furnace that is capable of heating the upper portion of a scrap by using heat generated during oxidation of carbon powder and oxygen.

In order to achieve the above object, the present invention, the carbon preheating means for heating the powder carbon using the high heat of the fume discharged from the electric furnace, and the preheated powder carbon to the inside of the electric furnace through the gas port ring It includes a carbon injection means for.

Therefore, the powdered carbon heated to a certain temperature is introduced into the electric furnace and reacted with oxygen to be released through the gas port ring, thereby oxidizing the unreacted oxygen inside the elbow or the duct.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a partial cutaway perspective view showing an electric furnace in which an unreacted oxygen combustion device is installed according to the present invention, and FIGS. 2 and 3 are detailed views showing some components of the unreacted oxygen combustion device according to the present invention. The operating state diagram of the unreacted oxygen combustion device according to the present invention.

According to the above drawings, on the roof 20 covering the upper part of the electric furnace 10, waste gas and dust generated when melting scrap and subsidiary materials in the electric furnace 10, and fumes, such as dust and molten slag, are sent to the dust collecting facility. The gas port ring 30 is installed, and the fume gas is sent to the dust collecting facility through the elbow 40 connected to the gas port ring 30 and the open gas duct 50 connected to the elbow 40.

The present invention is the carbon preheating means for preheating the powdered carbon using the high heat of the fume passing through the elbow 40 is installed in the elbow 40, the gas port ring 30 is provided in the preheating means Carbon injection means for injecting the carbon preheated through the gas port ring 30 into the electric furnace (10).

The preheating means is installed so as to communicate with the upper portion of the elbow 40, as shown in Figure 2, the housing 60 and the powder carbon hopper 61 is installed inside the housing 60, the high-temperature fume, the It is connected to the top of the hopper 61 through the top of the housing 60, the supply pipe 62 for supplying powdered carbon, is installed at the bottom of the hopper 61 and the gas port ring 30 through one side of the housing 60 Toward the carbon feed tube (63).

Inside the supply pipe 62 and the transfer pipe 63, a valve 64 for controlling the flow of the powdered carbon is provided. The valve 64 is connected to the drive cylinder 65 has a structure that can adjust the opening and closing amount of each pipe in accordance with the expansion and contraction operation of the drive cylinder (65).

In addition, the fume passing through the elbow 40 extends from the bottom of the hopper 61 to the elbow 40 in the housing 60 so that the fume passing through the housing 60 is guided into the housing 60 and exits through the housing 60. Vertically install the blocking plate 66 to be.

Therefore, since the fume is discharged from the lower portion of the housing 60 through the upper portion to the lower portion by the blocking plate 66, the contact time with the hopper 61 is increased, and thus carbon preheating can be performed more efficiently.

Meanwhile, looking at the injection means for injecting the preheated powder carbon into the electric furnace 10, an annular distribution pipe 70 is installed along the upper end of the gas port ring 30 and connected to the transfer pipe 63. ) And a carbon injection hole 71 formed at a predetermined interval along a lower end of the inner circumferential surface of the gas port ring 30 and the distribution pipe 70, and the respective injections through the interior of the gas port ring 30. Connection hole 72 connected to the hole 71 and the inlet gas pipe 73 for supplying a high-pressure inert gas for carbon injection is installed connected to one side of the transfer pipe (63).                     

Therefore, the carbon supplied through the transfer pipe 63 is sent to the distribution pipe 70 and the connection hole 72 by the inert gas supplied at a high pressure to the electric furnace through the injection hole 71 formed in the gas port ring 30. (10) It is injected inside to oxidize with unreacted oxygen.

Preferably, as shown in FIG. 3, the connection hole 72 connecting the distribution pipe 70 and the injection hole 71 is inclined toward the center of the gas port ring 30 so that the carbon is formed in the gas port ring. (30) To be sprayed toward the center.

Such a structure makes carbon more difficult to escape by concentrating carbon into the gas port ring 30 to form a conical film.

Hereinafter will be described the operation of the present invention.

When the operation of the electric furnace 10 is started, the high-temperature fume gas generated during the operation exits through the gas port ring 30 and heats the powdered carbon stored in the hopper 61 in the process.

That is, the powdered carbon is stored in the hopper 61 in the housing 60 through the supply pipe 62 and the hot fume gas exits the elbow 40 through the gas port ring 30 to the blocking plate 66. By circulating through the interior of the housing 60, the powder carbon stored in the hopper 61 in the housing 60 is heated by a high temperature fume gas.

When oxygen is blown through the oxygen lance 80 during operation of the electric furnace 10, the heated powder carbon is opened by the valve 65 according to the operation of the driving cylinder 65 installed in the transfer pipe 63. Along 63) to the distribution tube (70). And it is injected into the electric furnace 10 by the high-pressure inert gas flowing into the transfer pipe 63 through the inert gas pipe 73 connected to the lower transfer pipe 63.

That is, the inert gas is injected at high pressure into the injection hole 71 through each connection hole 72 in the distribution pipe 70, and powder carbon is also piggybacked on the inert gas and the electric furnace 10 through the injection hole 71. High pressure is injected into the interior.

The powdered carbon injected through the injection hole 71 reacts with the unreacted oxygen in the upper portion of the scrap charged in the electric furnace 10.

Here, the powdered carbon is reacted and oxidized as soon as it meets with oxygen because it is heated to a certain temperature, and the powdered carbon is sprayed toward the center of the gas port ring 30 to form a conical film, and oxygen strikes the film and mostly reacts. It will be so that the unreacted oxygen can not escape through the gas port ring (30).

On the other hand, since the oxidation reaction is performed directly above the scrap, heat generated during the oxidation reaction heats the upper part of the scrap.

When the melting operation and the oxygen blowing operation in the electric furnace 10 proceeds to a certain level or more, and most of the scrap is dissolved and formed into a molten metal, the injection of powder carbon is stopped.

According to the unreacted gas combustion apparatus of the electric furnace according to the present invention as described above, it is possible to react all of the unreacted gas in the interior of the electric furnace, the water-cooled pipe installed in the gas port ring, elbow, duct, etc. Can be prevented and the efficiency of the blown oxygen can be maximized.

In addition, by heating the upper part of the scrap to obtain an additional effect that can reduce the occurrence of scrap.

Claims (4)

Carbon preheating means for heating the powder carbon using the high heat of the fume discharged from the electric furnace, and carbon injection means for injecting the preheated powder carbon into the electric furnace through a gas port ring, The preheating means is installed so as to communicate with the upper elbow of the furnace loop, a housing in which a high temperature fume flows, a powder carbon hopper installed inside the housing, a supply pipe for supplying powder carbon connected to the upper end of the hopper, the hopper The unreacted oxygen combustion apparatus of the electric furnace including a carbon feed pipe installed at the bottom and extending toward the gas port ring through one side of the housing. delete According to claim 1, The injection means is installed along the upper end of the gas port ring and the annular distribution pipe connected to the transfer pipe, the carbon injection hole is formed at a predetermined interval along the lower end of the inner peripheral surface of the gas port ring, An electric furnace including a connection hole communicating with a distribution pipe and connected to each injection hole through the interior of the gas port ring, and connected to one side of the transfer pipe to supply a high pressure inert gas for carbon injection. Unreacted oxygen combustion device. The unreacted oxygen combustion apparatus of claim 3, wherein the connection hole and the injection hole are inclined toward the center of the gas port ring so that carbon is sprayed in a conical shape toward the center of the gas port ring.

Images