KR20100074453A - Reduction furnance having uniform gas stream - Google Patents

Abstract

PURPOSE: A reduction furnace with uniform gas distribution is provided to reduce the thermal load of a furnace when charge is provided to the furnace by uniforming the reduction rate of the charge particles. CONSTITUTION: A reduction furnace(100) is formed of a charge inlet(110) and a reduction gas inlet(170). Charge is loaded into the charge inlet. The charge inlet is formed on the upper part of the furnace. The reduction gas flows into the reduction gas inlet. The reduction gas inlet is formed on the bottom of the furnace. A dead man(180) is formed on the lower part of the reduction furnace.

Description

REDUCTION FURNANCE HAVING UNIFORM GAS STREAM}

The present invention relates to a reduction furnace for reducing ore containing iron oxide components and an apparatus for melting molten reduced ore to produce molten iron.

FIG. 1 shows a reduction furnace for reducing ore containing iron oxide components and an apparatus 1 for melting molten reduced ore to produce molten iron. As shown in FIG. 1, the apparatus 1 includes a reducing furnace 10 for blowing or reducing a precipitated ore such as pellets or lumps. The charge is introduced into the reduction furnace 10 through the charge inlet 11. The charges reduced in the reduction furnace 10 are quantitatively discharged by the discharge screw 13, and the discharged charges are supplied to the melting furnace 20 through the vertical down pipe 14 and the inclined down pipe 16. . A drop box 15 is provided in the vertical down pipe 14, and a nitrogen supply pipe (not shown) is connected to the drop box 15 to blow cooling nitrogen into the vertical down pipe 14. By this cooling nitrogen, the heat shock applied to the discharge screw 13 by the gas flowing back from the melting furnace 20 to the reducing furnace 10 can be reduced.

In the smelting furnace 20, coal is gasified to produce a reducing gas necessary for reducing the charges, and the charged charges reduced and supplied in the reduction furnace 10 are melted using the heat generated at this time.

The reducing gas generated in the melting furnace 20 is collected in the cyclone 22 and then blown into the reducing furnace 10 through the reducing gas inlet 17. The reduced reducing gas passes through the charge filling layer 30 in the form of an oxide to reduce the charge. However, the reduced reducing gas is not supplied to the center of the reduction furnace 10 due to the resistance by the charged charges, and mainly flows through the wall. Non-uniform distribution of the reducing gas causes a severe imbalance in the reduction rate for each position of the charges in the reduction furnace 10, and breaks the thermal balance of the melting furnace 20 by supplying the unreduced charges in the center to the melting furnace 20, It causes problems such as reduced production, higher fuel costs and lower utilization. In particular, when the size of the conventional reduction furnace 10 is enlarged for the purpose of increasing the capacity, the non-uniform distribution of the reducing gas becomes more serious, and if it is desired to increase the radial size of the reduction furnace 10, It becomes more difficult.

In addition, since the pressure loss occurs in the cyclone 22 when the reducing gas generated in the melting furnace 20 is blown into the reduction furnace 10 via the cyclone 22, the vertical down pipe 14 having relatively low pressure loss is produced. And back through the discharge screw 13 into the reduction furnace 10. Therefore, in order to prevent this, it is necessary to install the charge unreduced height h for the purpose of generating a pressure loss of the reducing gas flowing back into the reduction furnace 10 through the discharge screw 13, thereby unnecessarily You can only increase the height.

The present invention is designed to solve the problems of the prior art, the reduction gas supplied into the reduction furnace in the reduction process is not supplied to the center of the reduction furnace to remove the non-uniform distribution of the reducing gas flowing mainly through the wall, reducing furnace By increasing the reduction rate of the charges in the contents and making the reduction rate between the charged particles uniform, it is aimed to reduce the thermal burden of the melting furnace when the charges are supplied to the melting furnace, thereby increasing production, reducing fuel costs, increasing the operating rate and operating stability.

In addition, the present invention is to uniformly distribute the reducing gas in the radial direction of the reduction furnace, so that the capacity of the facility can be increased simply by increasing the radial direction of the reduction furnace and dead-man at the time of increasing the capacity of the reduction furnace. It aims to do it.

According to a first aspect of the present invention for achieving the above object, it is provided with a charge inlet for charging the charge, and a reducing gas inlet for blowing the reducing gas, the charge inlet is formed at the top, The reducing gas inlet is provided in the reduction furnace, characterized in that installed in the bottom.

According to the second aspect of the present invention, the reducing gas inlet is installed at the bottom of the existing Deadman located in the lower part of the reduction furnace.

According to a third aspect of the present invention, a passage communicating with the reducing gas inlet is formed in the deadman.

According to a fourth aspect of the invention, a plurality of passages are formed symmetrically in the radial direction.

According to a fifth aspect of the invention, the vertical down pipe from which the charge reduced by the reducing gas is discharged is filled with the charge in the normal operating state.

According to a sixth aspect of the present invention, a drop box is installed at an end of the vertical down pipe, and the drop box is provided with a discharge screw for quantitatively discharging the charge.

According to a seventh aspect of the invention, the vertical down pipe has a predetermined vertical length to produce a pressure loss of gas flowing back through the vertical down pipe to the reduction furnace.

According to the present invention, since the reducing gas is blown through the deadman disposed at the center of the bottom of the reduction furnace, the reduction rate of the charges in the reduction furnace is increased, the reduction rate between the charged particles is uniform, and when the charges are fed to the melting furnace, This reduces the thermal burden on the plant, resulting in increased production, lower fuel costs, increased utilization and operational stability.

In addition, the present invention by uniformly distributing the reducing gas in the radial direction of the reduction furnace, it is possible to increase the capacity of the equipment simply by increasing the radial direction of the reduction furnace and deadman at the time of increasing the capacity of the reduction furnace.

In addition, by moving the position of the discharge screw, which is the charge supply device from the lower end of the reduction furnace to the drop box portion, it is possible to prevent the high-pressure molten gas from flowing back into the reduction furnace by generating a differential pressure in the vertical down pipe.

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

2 shows a longitudinal sectional view of a reduction furnace 100 according to an embodiment of the invention. Referring to FIG. 2, a charge inlet 110 and a plurality of exhaust gas outlets 120 are provided at an upper portion of the reduction furnace 100. A dead-man 180 (or a dead-woman, or the same below) is installed at an inner lower end of the reduction furnace 100. Deadman 180 is installed to prevent the differentiation of the charge or the formation of a stagnation layer due to the charge load. A reducing gas inlet 170 is installed at the bottom of the dead man 180, and a passage is formed in the dead man 180 so that the reducing gas blown through the reducing gas inlet 170 may pass therethrough. The reducing gas inlet 170 is formed at the radial center of the reduction furnace 100, and a plurality of passages in the dead man 180 communicating with the reducing gas inlet 170 are radially symmetrically formed. desirable.

A vertical down pipe 140 connected to the reduction furnace 100 is installed at the lower part of the reduction furnace 100, and a drop box 150 is installed at an end of the vertical down pipe 140. The drop box 150 is equipped with a discharge screw 130 that is a removable charge quantity supply device. The inclined down pipe 160 connected to the dome portion of the melting furnace is installed below the drop box 150.

The charge is introduced into the reduction furnace 100 through the charge inlet 110. The charge reduced in the reduction furnace 100 is moved to the vertical down pipe 140, is discharged quantitatively by the discharge screw 130 formed at the end of the vertical down pipe 140. The discharged charge is supplied to the melting furnace through the inclined down pipe 160. On the other hand, the reducing gas is discharged through the exhaust gas outlet 120 after reducing the charge.

In the normal operating state, the interior of the reduction furnace 100 and the vertical down pipe 140 is filled with a charge.

According to the configuration of such a reducing furnace 100, instead of the conventional reducing gas inlet located in the middle wall of the reducing furnace, reducing gas can pass through the bottom of the deadman 180 is already installed in the lower end of the reducing furnace. By providing a reducing gas inlet 170 to blow the reducing gas of the melting furnace, a uniform distribution in the radial direction is induced from a nonuniform distribution phenomenon of the conventional reducing gas, thereby increasing the reducing gas utilization rate and the reduction rate of the charged material and making the reducing rate uniform. . In addition, when the charge is supplied to the furnace, the thermal burden on the furnace is reduced to increase production, reduce fuel costs, increase operation rate, and increase operation stability. In addition, since the uniform distribution of the reducing gas in the radial direction is possible, the capacity of the facility can be increased simply by increasing the radial direction of the reduction furnace 100 and the deadman 180 at the time of increasing the capacity of the reduction furnace 100.

In addition, by installing a discharge screw 130, which is a charge quantity supply device at the lower end of the reduction furnace, is installed in the drop box 150, a pressure loss is generated in the vertical down pipe 140, thereby reducing the high-pressure reducing gas in the melting furnace. Can be prevented from flowing back into the reduction furnace 100 through the discharge screw 130. That is, the high-pressure reducing gas in the melting furnace located below the inclined down pipe 160 is prevented from flowing back into the reduction furnace 100 due to the differential pressure of the vertical down pipe 140. Conventionally, in order to prevent the back flow of the reducing gas through the discharge screw 130, it was necessary to install the charge unreduced height (h) for the purpose of generating pressure loss of the reducing gas. Since the pressure loss occurs through, the height of the reduction furnace 100 may be reduced by the charge non-reduced height h of FIG. 1.

In addition, in the prior art, although nitrogen was blown into the vertical down pipe 140 for the purpose of reducing the thermal shock applied to the discharge screw 130 by the gas flowing back from the melting furnace to the reduction furnace 100, the reduction furnace 100 according to the present invention. In the vertical down pipe 140 does not require nitrogen to be blown because the nitrogen consumption can be reduced and operating costs can be reduced.

1 is a longitudinal cross-sectional view of a conventional apparatus for producing molten iron by melting a reduced ore and reduced ore containing iron oxide components.

2 is a longitudinal sectional view of a reduction furnace according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

100 Reduction Furnace 110 Filling Slot

120 Charging inlet 130 Ejection screw

140 vertical down pipe 150 drop box

160 inclined down pipe 170 reducing gas inlet

180 deadman

Claims (7)

The charge input port 110, the charge is charged, and And a reducing gas inlet 170 through which the reducing gas is blown, The charge inlet 110 is formed in the upper, the reducing gas inlet 170 is a reduction furnace, characterized in that installed in the bottom. The method according to claim 1, Further provided with a deadman 180 disposed below, The reducing gas inlet 170 is a reduction furnace, characterized in that installed in the bottom of the deadman (180). The method according to claim 2, Reduction furnace, characterized in that the passage in communication with the reducing gas inlet 170 is formed in the deadman (180). The method according to claim 3, Reduction furnace characterized in that the plurality of passages are formed symmetrically in the radial direction. The method according to any one of claims 1 to 4, Further provided with a vertical down pipe 140 through which the charge reduced by the reducing gas is discharged, Reduction furnace, characterized in that the inside of the vertical down pipe 140 is filled with a charge in the normal operating state. The method according to claim 5, Drop box 150 is installed at the end of the vertical down pipe 140, the drop box 150 is characterized in that the discharge screw 130 for quantitatively discharging the charge is installed. The method according to claim 6, The vertical down pipe (140) is a reduction furnace characterized in that it has a predetermined vertical length to generate a pressure loss of the gas flowing back to the reduction furnace through the vertical down pipe (140).

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