KR101407504B1 - Apparatus for supplying oxygen in furnace - Google Patents

Abstract

The present invention relates to an oxygen supplying apparatus connected to a converter, and discloses an oxygen supplying apparatus including a cooling means. An oxygen supply device for a converter according to the present invention comprises: a lance body disposed on an upper side of a converter; A nozzle body connected to an end of the lance body; An oxygen supply unit connected to the nozzle body and injecting oxygen to the converter through the nozzle body; A cooling medium supply unit connected to the nozzle body so as to be partitioned from the oxygen supply unit to cool the nozzle body by flowing the cooling medium to the nozzle body; And a cooling means coupled to the interior of the nozzle body and containing a working fluid therein and cooling the nozzle body as the working fluid circulates while being evaporated and condensed by capillary action when a temperature gradient occurs.

Converter, oxygen supply

Description

[0001] APPARATUS FOR SUPPLYING OXYGEN IN FURNACE [0002]

The present invention relates to a converter oxygen supply device.

Generally, steel is manufactured through a steelmaking process, a steelmaking process, and a rolling process.

In the above-mentioned manufacturing process, iron ore light (sintered ores), coke and lime are charged into the blast furnace. At this time, the coke is burned by hot air, and carbon monoxide generated in this process causes a reduction reaction with the iron ore, and a tangle is generated. The coke serves as a heat source for melting iron ore and serves to separate oxygen and iron from iron ore which is iron oxide.

The pig iron produced through the above-mentioned ironmaking process has a high carbon content and a considerable amount of impurities such as phosphorus, sulfur and silicon, which is high in hardness and weak in properties. The pig iron is refined to reduce the amount of carbon and to remove impurities. In the steelmaking process, flat steel, converter and electric furnace are applied.

In the converter, charcoal, a small amount of scrap iron and small coal are charged into the inside of the furnace, and oxygen having high purity is blown from above to oxidize and burn carbon, manganese, silicon, phosphorus and sulfur contained in the molten pig iron. At this time, the oxide is slagged and removed by lime, and a phosphor having a low phosphorus and oxygen content is produced because deoxidation and deoxidation are performed in parallel.

An oxygen supply device for supplying oxygen is connected to the converter. The oxygen supply device includes a lance body in the shape of a triple pipe and a lance nozzle in the form of a triple pipe in the lance body. A lance nozzle of a triple-tube type is welded to the end of the lance body. At this time, the lance nozzle is welded in the order of the outermost pipe from the pipe located inside.

The oxygen supply device is supplied with oxygen at normal temperature through a flow path at the center. Also, the air introduced into the lance nozzle through the outer channel of the oxygen supply device flows through the channel between the outer channel and the central channel to cool the lance body and the lance nozzle.

However, since the outer pipe of the lance nozzle is heated by a high temperature approaching approximately 1690 degrees Celsius, and the inner pipe is in contact with oxygen at room temperature, a difference in thermal expansion between the outer pipe and the inner pipe is remarkably generated. At this time, since the stress is concentrated on the tip of the nozzle due to the difference in thermal expansion, the outer side of the nozzle tip is plastically deformed to reduce the oxygen discharge port. Therefore, the injection speed of the oxygen injected from the lance nozzle is interfered with, and the reaction of the oxygen injected into the converter is slowed down. In addition, since the lance nozzle is welded to the end portion of the lance body, when the lance nozzle is thermally expanded, the weld portion having a relatively stronger embrittlement than the other portion can be broken.

Further, the oxygen injection pressure is lowered, so that a sufficient injection pressure is not generated so as to penetrate the slag layer on the charcoal accommodated in the converter and mix with the molten iron. Also, the productivity of the oxygen injected from the lance nozzle deteriorated due to the deterioration of the molten steel inside the converter and the increase in the time of the refining. In addition, by reacting with slag floated on top of the molten iron, the molten steel was substantially reduced in yield by rapidly increasing iron oxide.

Also, if the lance nozzle is deformed, the maintenance period for replacing with the new lance nozzle is shortened.

An object of the present invention is to provide an oxygen supply device capable of preventing deformation of a lance nozzle and securing discharge pressure and discharge amount of oxygen.

It is another object of the present invention to provide an oxygen supply device capable of improving the decarbonization performance of a lance nozzle, shortening the time for curing, and increasing the substantial yield of molten steel.

It is still another object of the present invention to provide an oxygen supply device capable of extending the replacement period of the lance nozzle.

An oxygen supply device according to the present invention comprises: a lance body disposed on an upper side of a converter; A nozzle body connected to an end of the lance body; An oxygen supply unit connected to the nozzle body and supplying oxygen to the converter through the nozzle body; A cooling medium supply unit connected to the nozzle body and partitioned by the oxygen supply unit to flow the cooling medium in the nozzle body to cool the nozzle body; The nozzle body is disposed so that one side of the nozzle body is exposed to the cooling medium and the other side of the nozzle body is extended from the one end of the nozzle body so as to be exposed to the converter, Cooling means for cooling the nozzle body as the working fluid is evaporated at the high temperature portion and condensed at the low temperature portion and circulated by the capillary phenomenon; And an oxygen discharge pipe connected to the oxygen supply unit and extending into the electric circuit via the interior of the cooling unit.

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The cooling means includes an outer tube disposed within the nozzle body and a heat pipe positioned within the outer tube and formed of a porous material.

The present invention has an effect that the lance nozzle is cooled by the cooling means to prevent the lance nozzle from being deformed, and the discharge pressure and discharge amount of oxygen can be secured.

The present invention has the effect of improving the decarbonization performance of the lance nozzle, shortening the curing time, and increasing the substantial yield of the molten iron.

The present invention minimizes the deformation of the lance nozzle, thereby increasing the replacement period of the lance nozzle.

In order to accomplish the above object, a specific embodiment of the oxygen supply apparatus according to the present invention will be described.

1 is a sectional view showing a converter including an oxygen supply device according to the present invention.

Referring to Fig. 1, a charcoal is accommodated in the inside of the converter 10. An oxygen supply device (100) is disposed above the converter (10) to inject oxygen into the molten iron. The lower end of the oxygen supply device 100 is disposed in a state of being inserted into the inside of the converter 10. In addition, the oxygen supply device 100 is arranged in a standing state in a vertical direction.

2 is a sectional view showing the oxygen supply device.

2, the oxygen supply device 100 includes a lance body 110 disposed on the upper side of the converter 10 and a nozzle body 120 coupled to an end of the lance body 110 . The lance body 110 and the nozzle body 120 have a pipe shape in which a cooling medium flow path is formed to allow a cooling medium to flow therein. At this time, the nozzle body 120 may be detached from the lance body 110 and be replaceably installed with a new nozzle body 120.

An oxygen supply unit 130 for supplying oxygen to the converter 10 through the nozzle body 120 is coupled to the nozzle body 120. The oxygen supply unit 130 may be detachably coupled to the fastening unit formed in the nozzle body 120. The oxygen supply unit 130 injects oxygen of 99.9% purity into the charcoal of the converter.

The nozzle body 120 is coupled with a cooling medium supply unit 140 for supplying a cooling medium to the nozzle body 120 and the lance body 110. The cooling medium flows through the nozzle body 120 and the lance body 110 to cool the nozzle body 120 and the lance body 110. At this time, the cooling medium supply unit 140 may be detachably coupled to the coupling unit formed in the nozzle body 120. [ Here, air or water may be used as the cooling medium.

Cooling means (150, 155) are disposed inside the nozzle body (120). The cooling means includes an outer tube 155 disposed inside the nozzle body 120 and a heat pipe 150 disposed inside the outer tube 155 in the form of a double pipe. An inner passage 151 is formed on the inner side of the heat pipe 150 and an outer passage 152 is formed on the outer side of the heat pipe 150. The working fluid is received in the inner and outer flow paths (151, 152) of the cooling means (150, 155). At this time, the heat pipe 150 is formed of a porous material so that when the temperature gradient is generated, the working fluid evaporates at the high temperature portion and is circulated while being condensed at the low temperature portion. In addition, the interior of the outer tube 155 may be maintained at a vacuum of approximately 10 < ^-4 > torr so that the working fluid operates at approximately 600 degrees centigrade.

The cooling means 150 and 155 may be installed such that one side is exposed to the converter and the other side is exposed to the cooling medium. At this time, the partition member 125 is disposed inside the nozzle body 120 to partition the flow path of the oxygen supply unit 130 and the cooling medium supply unit 140. The partition member 125 is interposed between the inner surface of the nozzle body 120 and the outer surface of the cooling means 150 and 155. In addition, the cooling means 150 and 155 have a shape extending from the lower end of the nozzle body 120 downward by a predetermined length.

An oxygen discharge pipe 133 extends through the inside of the cooling unit 150 and 155 to the oxygen supply unit 130. The lower end of the oxygen discharge pipe 133 passes through the lower end of the cooling means 150 and 155.

The operation of the oxygen supply apparatus according to the present invention constructed as described above will be described.

Referring to FIG. 2, high-purity oxygen is injected into the furnace through the oxygen supply unit 130. At this time, the injection pressure of the oxygen should be formed to penetrate the slag layer floating above the molten iron and to provide a sufficient amount of oxygen to the molten iron. The oxygen taken in the charcoal line oxidizes and removes impurities such as phosphorus, silicon and the like contained in the charcoal line.

In addition, the cooling medium supply unit 140 allows the cooling medium to flow into the nozzle body 120. At this time, the cooling medium cools approximately half of the upper side of the nozzle body 120 and the cooling means (150, 155).

Since the converter 10 is at a temperature of approximately 1690 degrees centigrade, the cooling means 150 and 155 are heated by the heat generated in the converter. The upper side of the cooling means (150, 155) becomes a low temperature portion and the lower side of the cooling means (150, 155) becomes a high temperature portion, and a large temperature gradient is generated on the upper side and the lower side of the cooling means.

At this time, the working fluid is moved to the lower side of the inner flow path 151 of the cooling means (150, 155). When the working fluid of the high temperature portion is heated, the working fluid evaporates and flows into the outer flow path 152 of the cooling means 150 and 155 by capillary phenomenon. The working fluid of the outer passage 152 moves upward and reaches the low temperature portion. The working fluid at the low temperature part is condensed while releasing heat to the cooling medium. The condensed working fluid flows into the inner passage 151 by capillary action. The nozzle body 120 is cooled by the circulation of the working fluid. Here, since the thermal conductivity of the cooling means 150 and 155 is several hundred times larger than that of copper, the temperature gradient in the longitudinal direction of the nozzle body 120 is minimized.

Since the oxygen discharge pipe 133 is disposed inside the cooling means 150 and 155, the oxygen discharge pipe 133 is cooled by the cooling means 150 and 155. Therefore, the time for deforming the discharge port of the oxygen discharge pipe 133 can be prolonged.

In addition, since the nozzle body 120 is cooled by the cooling means 150 and 155, it is possible to minimize the deformation of the nozzle body 120 due to heat. Further, since the discharge port of the nozzle body 120 is hardly deformed, the discharge pressure and discharge amount of oxygen can be secured. Therefore, it is possible to inject oxygen into the molten iron at a sufficient injection pressure, so that the decarbonization performance of the molten iron can be improved, the time for the molten iron can be shortened, and the substantial yield of molten iron can be increased.

INDUSTRIAL APPLICABILITY The present invention is industrially remarkable because it can secure the discharge pressure and discharge amount of oxygen, improve the decarbonization performance, and increase the substantial yield of charcoal.

1 is a sectional view showing a converter including an oxygen supply device according to the present invention.

2 is a cross-sectional view showing the oxygen supply device of FIG.

Claims (4)

A lance body disposed on the upper side of the converter; A nozzle body connected to an end of the lance body; An oxygen supply unit connected to the nozzle body and supplying oxygen to the converter through the nozzle body; A cooling medium supply unit connected to the nozzle body and partitioned by the oxygen supply unit to flow the cooling medium in the nozzle body to cool the nozzle body; The nozzle body is disposed so that one side of the nozzle body is exposed to the cooling medium and the other side of the nozzle body is extended from the one end of the nozzle body so as to be exposed to the converter, Cooling means for cooling the nozzle body as the working fluid is evaporated at the high temperature portion and condensed at the low temperature portion and circulated by the capillary phenomenon; And An oxygen discharge tube connected to the oxygen supply section and extending into the electric circuit via the inside of the cooling means, And an oxygen supply device for supplying oxygen to the reactor. delete delete The method according to claim 1, Wherein the cooling means comprises an outer tube disposed within the nozzle body and a heat pipe positioned within the outer tube and formed of a porous material.

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