KR101778435B1 - Reaction inducing device for electric furnace - Google Patents

Abstract

The present invention provides a reaction inducing device for an electric furnace having improved such that ignition of a flame automatically occurs to improve reactivity when oxygen gas blows in. According to an embodiment of the present invention, the reaction inducing device for the electric furnace relates to a reaction inducing device for the electric furnace coupled to an end of an oxygen pipe and configured to generate a flame to ignite blown-in oxygen wherein the reaction inducing device comprises: a cylindrical coupling portion coupled to the end portion of the oxygen pipe; and a conductivity coupling portion supplied to an outer circumferential edge of the cylindrical coupling portion, and configured to generate an arc by a medium of electrical conductivity with a material blown in the electric furnace.

Description

TECHNICAL FIELD [0001] The present invention relates to a reaction induction device for an electric furnace,

The present invention relates to a reaction induction device for an electric furnace that induces an oxidation reaction of a reactant to be added for improving the reactivity of an electric furnace.

Generally the electric furnace 10 includes an electric furnace main body 12 in which a raw material P such as scrap is charged to be melted and an upper portion of the furnace main body 12 is opened / And an electrode rod 16 which is inserted into the cover 14 and generates an arc for dissolving the raw material P is provided.

On the other hand, the raw material P such as scrap iron charged into the electric furnace 10 is melted by the heat source by the arc of the electrode rod 16. At this time, oxygen gas which is a combustion gas is supplied from one side of the electric furnace main body 12 An inlet port 18 for blowing the oxygen pipe 20 is formed on one side of the electric furnace main body 120 for the introduction.

The combustion gas, that is, the oxygen gas improves the reaction rate of the scrap metal, improves the melting rate by using the oxidation heat generated when the components contained in the molten metal (P1) are oxidized, Remove and adjust the elements.

On the other hand, the raw material adjacent to the electrode rod 16 in the melting operation of the electric furnace 10 is melted by the electrode rod 16 and changed into the form of the molten metal P1. However, the raw material P remote from the electrode rod 16 is not directly transferred to the oxidation column and the arc column of the electrode rod 16, so that the dissolution can not be performed quickly. These raw materials P are entirely transferred with the same current but there is a difference at the point of dissolution.

At a certain point in time, the oxygen pipe 20 is injected into a portion adjacent to the scrap iron, and then oxygen is discharged. At this time, oxygen is not reacted because the ignition source is not formed when the molten steel is not completely dissolved, Is sucked and discharged through the dust collecting pipe (30) provided at one side of the dust collecting pipe (12).

However, when the raw material is melted in the furnace body 12 and changed into the molten metal P1, oxygen is ignited by the heat of fusion generated at this time, thereby raising the temperature of the exhaust gas. 30, the inside of the dust collecting tube 30 is damaged in the process of being sucked and discharged. In addition, in the dust collecting tube 30, the oxygen gas exhausted in an unburned state is ignited by a high temperature or the like, and sparks (S) may occur, thereby causing damage to the dust collecting tube 30 and related equipment .

Therefore, conventionally, oxygen is injected into a site where the raw material P is melted in the electric furnace body 12, and as a result, the entire melting time is increased as the oxygen injection time is delayed, Melting does not occur and does not react with oxygen, which causes waste of oxygen.

Therefore, conventionally, even when the melting of the raw material P is completed in the electric furnace 10, it is necessary to continuously supply the oxygen gas to remove the byproducts and the like. Therefore, to be.

It is an object of the present invention to provide a reaction induction device for an electric furnace in which spark ignition is automatically generated so as to improve the reactivity at the time of blowing oxygen gas.

A reaction induction device for an electric furnace according to an aspect of the present invention is a reaction induction device for an electric furnace which is coupled to an end of an oxygen pipe introduced to introduce oxygen into an electric furnace and generates a flame so that the introduced oxygen is ignited, A cylindrical coupling portion coupled to the coupling portion; And a conductive coupling portion provided at an outer periphery of the cylindrical coupling portion and generating an arc through electrical conduction between the raw material loaded into the electric furnace and the conductive coupling portion integrally coated with the end portion of the cylindrical coupling portion Conductive coating layer.
According to another aspect of the present invention, there is provided a reaction induction apparatus for an electric furnace, which is coupled to an end of an oxygen pipe introduced to introduce oxygen into an electric furnace and generates a flame to ignite the input oxygen, A cylindrical coupling portion coupled to an end of the cylindrical portion; And a conductive coupling portion provided at an outer periphery of the cylindrical coupling portion and generating an arc through electrical conduction between the raw material charged into the electric furnace and the conductive coupling portion is formed of a conductive material coupled to an end portion of the cylindrical coupling portion And a ring member formed thereon.

The cylindrical coupling portion may further include a ring flange having an inner diameter corresponding to an outer diameter of the oxygen pipe and extending to an outer circumferential edge at an end portion inserted into the oxygen pipe.

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In addition, the conductive coating layer may have a plurality of concavo-convex portions formed on its surface.

The apparatus may further include a plurality of exhaust holes formed at an end of the cylindrical coupling portion to divide and discharge oxygen discharged from the oxygen pipe.

In addition, the exhaust hole may be formed such that an exit cross-sectional area thereof extends in a direction in which oxygen is exhausted.

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Further, the ring member may have a plurality of concave-convex portions formed on its surface.

In addition, the end of the ring member may include a plurality of exhaust holes formed to close the end portion of the oxygen pipe, and to divide and discharge oxygen discharged from the oxygen pipe.

The exhaust hole may be formed such that the exit cross-sectional area expands in a direction in which oxygen is exhausted.

According to an embodiment of the present invention, oxygen gas may be introduced from the beginning of the steelmaking process of the electric furnace, and an arc flame may be generated to react the oxygen gas. In this way, It is possible to accelerate the operation, and the oxygen gas to be introduced reacts without being discharged to the molten steel and the collecting pipe, so that the reaction efficiency of the oxygen gas can be improved.

1 is a schematic view showing a general steelmaking process of an electric furnace.
2 is a schematic view showing a steelmaking process of an electric furnace having a reaction induction device for an electric furnace according to an embodiment of the present invention.
3 is an enlarged perspective view of a reaction induction device for an electric furnace according to an embodiment of the present invention;
4 is an enlarged cross-sectional view of a reaction induction device for an electric furnace according to an embodiment of the present invention.
5 is a sectional view showing a modification of the reaction induction device for an electric furnace according to one embodiment of the present invention.
FIG. 6 is a schematic view showing a state where a reaction induction device for an electric furnace according to another embodiment of the present invention is inserted into an electric furnace; FIG.
7 is an enlarged perspective view of a reaction induction device for an electric furnace according to another embodiment of the present invention;
8 is an enlarged cross-sectional view of a reaction induction device for an electric furnace according to another embodiment of the present invention.
9 is a sectional view showing a modification of the reaction induction device for an electric furnace according to another embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. The embodiments of the present invention can be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. The shape and the size of the elements in the drawings may be exaggerated for clarity and the same elements are denoted by the same reference numerals in the drawings.

FIG. 2 is a schematic view showing a steelmaking process of an electric furnace equipped with a reaction induction device for an electric furnace according to an embodiment of the present invention, FIG. 3 is an enlarged perspective view of a reaction induction device for an electric furnace according to an embodiment of the present invention And FIG. 4 is an enlarged cross-sectional view of a reaction induction device for an electric furnace according to an embodiment of the present invention.

2 to 4, the reaction induction device 150 for an electric furnace according to the present embodiment is a device that is coupled to an end portion of an oxygen pipe 120 to be charged with oxygen during a steelmaking process in an electric furnace 110, May be provided to generate an arc spark (S) such that oxygen is ignited after being input.

The electric furnace 110 includes an electric furnace main body 112 in which a raw material P such as scrap iron is stored and an upper portion of the furnace main body 112 is provided with a cover And an electrode rod 116 inserted into the cover 114 and generating an arc for dissolving the raw material. A dust collecting pipe 130 for discharging the gas generated from the electric furnace body 112 may be connected to one side of the cover 114.

On the other hand, oxygen gas is introduced into one side of the furnace main body 112 in order to improve the reactivity and remove and adjust unnecessary elements contained in the molten metal P1 in the process of dissolving the raw material P by the electrode rod 116 The oxygen pipe 120 can be taken in, and the intake port 118 for blowing the oxygen pipe 120 can be formed on one side.

At the end of the oxygen pipe 120, an electric furnace reaction inducing device 150 may be provided to generate an arc spark S in the oxygen to be injected.

The electric furnace reaction induction device 150 may include a generally cylindrical cylindrical engagement portion 152 provided to be inserted into the end portion of the oxygen pipe 120 as specifically shown in Figs. 3 and 4 have.

The conductive coupling portion 154 may be provided on the outer circumference of the cylindrical coupling portion 152 to generate an arc by being electrically connected to the raw material loaded in the electric furnace 110.

The cylindrical coupling portion 152 may further include a ring flange 156 that can be provided to have an inner diameter into which the outer diameter of the oxygen pipe 120 is inserted and which extends to an outer circumferential edge at an end portion inserted into the oxygen pipe 120 . The ring flange 156 is configured to be easily gripped when the reaction induction device 150 for an electric furnace is damaged or broken.

In addition, the conductive coupling portion 154 may include a conductive coating layer 154a integrally coated on the end of the cylindrical coupling portion 152.

For example, the conductive coating layer 154a may be provided to generate an arc spark S by a current applied to a raw material of the electric furnace 110. For example, the conductive coating layer 154a may be formed of a metal material such as iron, A film layer of a material can be formed by coating.

The reaction induction device 150 for an electric furnace may be disposed adjacent to the raw material P of the electric furnace main body 112 by shaking due to discharge of oxygen gas in a state of being coupled to an end of the oxygen pipe 120, In this process, oxygen injected from the oxygen pipe 120 is ignited and reacted by the arc spark S generated between the raw material and the conductive coating layer 154a.

That is, the reaction induction device for electric furnace 150 can react the oxygen gas from the beginning of the supply of the oxygen gas, thereby improving the dissolving performance of the raw material P, It is possible to prevent the oxygen gas from being discharged in an unreacted state and to prevent the oxygen gas from being completely charged into the electric furnace main body 112 and then to react with the rapid heating of the internal gas It is possible to prevent ignition and damage to the dust collecting tube 130 caused thereby.

An end of the cylindrical coupling portion 152 may be closed and a plurality of discharge holes 153 may be formed at the end of the cylindrical coupling portion 152 to uniformly inject the oxygen gas supplied from the oxygen pipe 120. [ May be formed.

Preferably, the discharge hole 153 may be formed in such a manner that the cross-sectional area of the outlet is expanded in a direction in which the oxygen gas is discharged. Accordingly, the gas diffusing property of the oxygen gas can be improved, Can be prevented.

In addition, a check valve may be installed inside the cylindrical coupling portion 152 to limit the discharge direction of oxygen gas to the inside of the electric furnace main body 112 to prevent flame backflow during back flow of the oxygen gas.

In addition, although the conductive coupling portion 154 is described as being integrally coated on the end of the cylindrical coupling portion 152 in the present embodiment, as shown in FIG. 5, in the coating process, ) May be formed.

The conductive coupling portion 154 is configured such that the electric current to be conducted to the raw material P is concentrated by the irregular portion 154b of the conductive coupling portion 154 and further promotes the generation of the spark spark S, Can be further promoted.

Accordingly, the raw material P can be quickly melted into the molten metal P1 by the heat of fusion due to the electric current delivered to the electrode rod 116 and the heat of reaction due to the reaction of the oxygen gas.

In this embodiment, the conductive coupling portion 154 includes the conductive coating layer 154a integrally coated on the end of the cylindrical coupling portion 152. However, The shape is not limited and can be variously modified.

6 is a schematic view showing a state in which a reaction induction device for an electric furnace is inserted into an electric furnace according to another embodiment of the present invention, and FIG. 7 is an enlarged view of a reaction induction device for an electric furnace according to another embodiment of the present invention And FIG. 8 is an enlarged cross-sectional view of a reaction induction device for an electric furnace according to another embodiment of the present invention.

6 to 8, in the present embodiment, the reaction induction device 250 for an electric furnace includes a cylindrical coupling portion 252, and the end of the cylindrical coupling portion 252 may be in an open form.

In addition, the conductive coupling portion 254 may be coupled to the end of the cylindrical coupling portion 252. Here, the conductive coupling portion 254 may include a ring member 254a formed of a conductive material, which is coupled to the end of the cylindrical coupling portion 252. [

The cylindrical coupling portion 252 may further include a ring flange 256 extending to an outer periphery at an end portion of the cylindrical coupling portion 252 inserted into the oxygen pipe 120. The ring flange 256 is configured to be easily gripped when the electric induction apparatus 250 is damaged or damaged.

For example, the ring member 254a, which is the conductive coupling portion 254, may be provided so as to generate the arc spark S by the electric current passing through the raw material of the electric furnace 110. For example, Iron or the like, or a carbon material.

The reaction induction device 250 for an electric furnace may be arranged adjacent to the raw material P of the electric furnace main body 112 by shaking due to discharge of oxygen gas in a state of being coupled to the end of the oxygen pipe 120, Oxygen injected from the oxygen pipe 120 is ignited and reacted by the arc spark S generated between the raw material P and the conductive coupling portion 254 in this process so that the raw material P reacts with the molten metal P1 ). ≪ / RTI >

That is, the reaction induction device 250 for an electric furnace can react the oxygen gas from the beginning of the supply of the oxygen gas, thereby improving the melting performance of the raw material P, It is possible to prevent the oxygen gas from being discharged in an unreacted state and to prevent the oxygen gas from being completely charged into the electric furnace main body 112 and then to react with the rapid heating of the internal gas It is possible to prevent ignition and damage to the dust collecting tube 130 caused thereby.

An end of the cylindrical coupling portion 252 may be closed and a plurality of discharge holes 253 are formed in the end of the cylindrical coupling portion 252 to uniformly inject the oxygen gas supplied from the oxygen pipe 120. [ May be formed.

Preferably, the discharge hole 253 may be formed such that the cross-sectional area of the outlet is extended in a direction in which the oxygen gas is discharged. Accordingly, the oxygen gas can be injected more uniformly, have.

In addition, a check valve may be installed inside the cylindrical coupling portion 252 to limit the discharge direction of oxygen gas to the inside of the electric furnace main body 112 to prevent flame backflow during back flow of the oxygen gas.

9, the conductive coupling portion 254 is coupled to the end of the cylindrical coupling portion 252, and a plurality of concave and convex portions 254b may be formed on the surface of the cylindrical coupling portion 252 .

The conductive coupling portion 254 is formed so that the electric current to be conducted to the raw material is concentrated by the concave and convex portion 254b of the conductive coupling portion 254 and further promotes the generation of the spark spark S, Can be further promoted.

In the reaction induction device 250 for an electric furnace described above, oxygen gas is supplied to the oxygen pipe 120, and the arc spark S and the oxygen gas react with each other at the contact point, so that raw materials such as scrap iron can be easily dissolved, The dissolution of the raw material can be diffused by the oxygen gas.

Also, the oxygen gas supplied from the oxygen pipe 120 is diffused at a wide angle while being discharged by the plurality of discharge holes 253, so that the contact with the arc spark S is facilitated. In addition, since the melting of the raw material occurs rapidly, the oxygen pipe 120 can be immersed in the molten metal that is held on the bottom, and the reaction can be diffused to the raw material positioned on the bottom.

It is to be understood that the present invention is not limited to the above-described embodiments and accompanying drawings, and that various changes, substitutions, changes, and alterations without departing from the spirit of the invention as set forth in the claims, It will be clear to those who have.

110: electric furnace 112: electric furnace body
114: Cover 116: Electrode
118: Extraction port 120: Oxygen pipe
130: Collector tube 150: Reactor for electric furnace
152: Cylindrical coupling part 153: Exhaust hole
154: Conductive bonding portion 154a: Conductive coating layer
156: ring flange

Claims (10)

A reaction induction device for an electric furnace which is connected to an end portion of an oxygen pipe blown into an electric furnace so as to inject oxygen and generates a flame so that the injected oxygen is ignited,
A cylindrical coupling portion coupled to an end of the oxygen pipe; And
A conductive coupling portion provided at an outer circumference of the cylindrical coupling portion and generating an arc through electrical conduction with a raw material charged in the electric furnace;
, ≪ / RTI &
And the conductive coupling portion includes a conductive coating layer integrally coated on an end of the cylindrical coupling portion. A reaction induction device for an electric furnace which is connected to an end portion of an oxygen pipe blown into an electric furnace so as to inject oxygen and generates a flame so that the injected oxygen is ignited,
A cylindrical coupling portion coupled to an end of the oxygen pipe; And
A conductive coupling portion provided at an outer circumference of the cylindrical coupling portion and generating an arc through electrical conduction with a raw material charged in the electric furnace;
, ≪ / RTI &
Wherein the conductive coupling portion includes a ring member formed of a conductive material coupled to an end of the cylindrical coupling portion. The method according to claim 1 or 2,
Wherein the cylindrical coupling portion further includes a ring flange having an inner diameter corresponding to an outer diameter of the oxygen pipe and extending to an outer periphery at an end portion inserted into the oxygen pipe. The method according to claim 1,
Wherein the conductive coating layer has a plurality of concavo-convex portions formed on a surface thereof. The method according to claim 1 or 2,
And a plurality of exhaust holes formed at an end of the cylindrical coupling portion to divide and discharge oxygen discharged from the oxygen pipe. The method of claim 5,
Wherein the outlet hole is formed so that the cross-sectional area of the outlet extends in a direction in which oxygen is discharged. delete The method of claim 2,
Wherein the ring member has a plurality of concavo-convex portions formed on a surface thereof. The method according to claim 2 or 8,
Wherein the end portion of the ring member is formed so as to close an end portion of the oxygen pipe and includes a plurality of exhaust holes for dividing and discharging oxygen discharged from the oxygen pipe. The method of claim 9,
Wherein the outlet hole is formed so that the cross-sectional area of the outlet extends in a direction in which oxygen is discharged.

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