KR102151426B1 - Equipment for preventing reclained lump steel on the converter throat - Google Patents

Abstract

The present invention provides a device for preventing adhesion of a converter furnace. The converter furnace anti-adhesion facility includes a converter forming a furnace hole and having an accommodation space for receiving molten steel therein; A discharge comprising a magnet disposed in the periphery of the furnace, and directing the flow of magnetic lines of force formed through the magnet to the outside of the furnace to induce the metal components remaining in the accommodation space to be discharged to the outside of the furnace. Induction part; And a gas supply unit disposed in the furnace opening, wherein the gas supply control unit supplies a plurality of gases through the gas supply unit so that the gas component composition of the exhaust gas is a predetermined reference gas component composition to form a reference gas supply amount; Includes.

Description

Equipment for preventing reclained lump steel on the converter throat}

The present invention relates to an anti-adhesion facility for a converter furnace, and more particularly, to a facility for preventing anti-adhesion of a converter furnace, which can stabilize the flow of flue gas while preventing the current attachment in the furnace.

In general, a converter is a facility that produces molten steel by blowing oxygen into the molten iron to remove carbon.

When a large amount of oxygen is supplied to the converter through a lance, exhaust gas of CO component is generated.

The flue gas generated at this time and slag, Fe, etc. in the converter are combined to generate now.

Now that is generated as described above, it accumulates and grows due to flow flow failure in the converter furnace.

Accumulated in the furnace now causes stagnation of exhaust gas in the converter, which causes adverse reactions such as explosions.

In addition, the skirt, which is the exhaust gas dust collecting facility on the upper part of the converter, cannot be brought into close contact with the furnace. Due to this, there is a problem in that harmful exhaust gas cannot be properly collected and is discharged to a factory to deteriorate the environment.

Conventionally, workers are required to physically remove the current accumulated in the converter from time to time.

For example, a scrap chute is used to remove the converter furnace. At this time, there is a problem that productivity decreases because the mouth ring of the converter furnace is damaged by the scrap chute and cannot be produced within the corresponding time.

Meanwhile, the flue gas generated from the converter depends on the ore inside the converter, the amount of skirt opening, and the amount of oxygen supplied.

The exhaust gas described above also contains a CO component or other N2, H gases.

When the composition of the exhaust gas is unstable, the exhaust gas may be exploded, so a stable composition of the exhaust gas is important.

The composition of the exhaust gas is basically adjusted through ore, skirt opening amount, oxygen supply amount, etc.

However, when the exhaust gas flows into the skirt, there is a problem that the composition of the exhaust gas cannot be changed or adjusted after that.

Prior literature related to the present invention is Korean Patent Application Publication No. 10-2010-0076201 (published on July 6, 2010).

The first object of the present invention is to provide a device for preventing the current from accumulating in the converter.

In addition, a second object of the present invention is to provide a facility to prevent adhesion of a converter furnace to supply gases such as N2, Ar, O2 to the furnace so that the composition of the exhaust gas can be changed or adjusted before the skirt is introduced.

In order to achieve the above object, the present invention provides a device for preventing adhesion of a converter furnace.

The converter furnace anti-adhesion facility includes a converter forming a furnace hole and having an accommodation space for receiving molten steel therein; A discharge comprising a magnet disposed in the periphery of the furnace, and directing the flow of magnetic lines of force formed through the magnet to the outside of the furnace to induce the metal components remaining in the accommodation space to be discharged to the outside of the furnace. Induction part; And a gas supply unit disposed in the furnace opening, wherein the gas supply control unit supplies a plurality of gases through the gas supply unit so that the gas component composition of the exhaust gas is a predetermined reference gas component composition to form a reference gas supply amount; Includes.

The converter, a converter body in which the furnace is formed at an upper end, the accommodation space is formed, a furnace iron shell is formed on an upper end of the converter body to surround the furnace, and a cooling water flow path is formed therein, and the furnace ball Including a mouse ring disposed on the upper end of the nogu iron skin to surround,

It is preferable that the discharge induction part is installed inside the furnace shell.

In addition, the discharge induction unit, the electromagnetic induction coil disposed inside the furnace shell so as to surround the furnace, and to provide a current to the electromagnetic induction coil to magnetize the electromagnetic induction coil to become the magnet to form a magnetic field. Including a current provider,

The force generated by the magnetic field is preferably formed along the outside of the furnace.

In addition, the discharge induction part includes a permanent magnet disposed inside the furnace shell,

An S pole is formed on one side of the permanent magnet, and an N pole is formed on the other side,

It is preferable that the other surface portion of the permanent magnet on which the N-pole is formed is disposed to face the accommodation space of the converter. The permanent magnet is the magnet.

In addition, the gas supply control unit includes a collection unit that collects the exhaust gas, a measurement unit that measures a gas component of the collected exhaust gas, and a composition variable unit that adjusts the measured gas component to achieve the preset reference gas composition. And, comprising a gas supply unit for supplying the inner space of the furnace through the furnace by forming the reference gas composition of the plurality of gases,

It is preferable that the gas supply unit supplies a plurality of gases to achieve the reference gas supply amount.

In addition, the gas supply unit, a plurality of unit gas supplies supplying the gas, are disposed inside the mouth ring, through one end of the inner circumference of the mouth ring by receiving a plurality of the gas from the plurality of unit gas supply And a gas supply pipe supplying a plurality of the gases supplied through the other end exposed through the furnace to the inner region of the furnace,

It is preferable that the unit gas supply units control the plurality of gases to form the reference gas composition and to achieve the reference gas supply amount.

According to the above solution, the present invention has an effect of preventing the current of the converter from accumulating.

In addition, the present invention has the effect of supplying gases such as N2, Ar, O2 to the furnace so that the composition of the exhaust gas can be changed or adjusted before the skirt is introduced.

1A is a view showing a device for preventing adhesion of a converter furnace according to the present invention. 1B is a diagram illustrating an electromagnetic field generated when the electromagnetic induction coil of FIG. 1A is magnetized.
FIG. 2 is a view showing a device for preventing attachment of a converter furnace equipped with a gas supply control unit according to the present invention.
3 is a view showing the configuration of a gas supply control unit according to the present invention.
4 is a view showing a device for preventing attachment of a converter furnace to which another example of the discharge induction unit according to the present invention is applied.
5 is a view showing a device for preventing adhesion of a converter furnace equipped with a gas supply control unit according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings so that those skilled in the art can easily implement the present invention.

The present invention may be implemented in various different forms, and is not limited to the embodiments described herein.

In order to clearly describe the present invention, parts irrelevant to the description have been omitted, and the same reference numerals are assigned to the same or similar components throughout the specification.

Hereinafter, it means that an arbitrary configuration is provided or arranged on the "upper (or lower)" or "upper (or lower)" of the substrate, wherein the arbitrary configuration is provided or arranged in contact with the upper (or lower) surface of the substrate. Means that.

In addition, it is not limited to not including other configurations between the substrate and any configuration provided or disposed on (or under) the substrate.

Hereinafter, with reference to the accompanying drawings, a description will be made of a device for preventing adhesion of the converter furnace of the present invention.

1A is a view showing a device for preventing adhesion of a converter furnace according to the present invention. 1B is a diagram illustrating an electromagnetic field generated when the electromagnetic induction coil of FIG. 1A is magnetized.

Referring to FIG. 1A, the apparatus for preventing adhesion of the converter furnace according to the present invention largely includes a converter 100, an exhaust induction part 200, and a gas supply control unit 300 (see FIG. 3).

Converter (100)

The converter 100 according to the present invention has a converter body 110.

An accommodation space in which molten steel is accommodated is formed inside the converter body 110.

A furnace bulb 111 is formed at the upper end of the converter body 110. The furnace hole 111 communicates with the accommodation space.

The furnace opening 111 forms a flow path for exhausting exhaust gas generated from the inside of the converter body 110 to the outside.

A furnace iron shell 120 is formed on the upper end of the converter body 110 so as to surround the furnace 111.

A space is formed inside the furnace iron shell 120.

Cooling water is accommodated in the furnace shell shell 120. The cooling water may be circulated through a separate circulation device. The cooling water serves to cool the temperature of the exhaust gas exhausted through the furnace opening 111.

The inner periphery of the furnace iron shell 120 forms a slope extending from the top to the bottom.

Although not shown in the drawing, guide grooves along the upper and lower sides of the inclined furnace iron shell 120 are formed. The guide grooves may serve to guide exhaust gas discharge.

In addition, a cooling coil may be further disposed in the vicinity of the inner periphery of the furnace iron shell 120. The cooling coil is cooled to a predetermined temperature through a current provided from a separate current device. This serves to additionally cool the exhaust gas.

In addition, a mouse ring 130 is installed at the upper end of the furnace iron skin 120 so as to be disposed on the upper end of the converter body 110. The inner end of the mouse ring 130 may be further extended by a predetermined length along the hollow of the furnace iron shell 120.

A flow path through which gas is supplied is formed in the mouth ring 130. Its configuration will be described later.

Discharge induction part (200)

The discharge induction part 200 according to the present invention is disposed inside the furnace iron shell 120 described above.

The discharge induction part 200 serves to guide the flow of the magnetic force line toward the outside of the furnace hole 111 so that the metal component remaining in the accommodation space is discharged to the outside of the furnace hole 111.

An example of the discharge induction part 200 according to the present invention will be described.

The discharge induction unit 200 according to the present invention includes an electromagnetic induction coil 210 and a current provider 220.

The electromagnetic induction coil 210 is disposed inside the furnace ball shell 120 so as to surround the furnace ball 111.

The number of windings of the electromagnetic induction coil 210 is preferably designed to be proportional to the amount of metal components such as slag.

The current provider 220 provides a set current to the electromagnetic induction coil 210. The intensity of the provided current may be variably controlled.

Accordingly, the electromagnetic induction coil 210 receiving current is formed as an electromagnet by forming a magnetic field line, that is, an electromagnetic field as the current flows. The electromagnetic induction coil 210 generates an electromagnetic force proportional to the strength of the supplied current. Here, the force generated by the magnetic field, that is, the flow of the magnetic force line, is formed along the outside of the furnace hole 111. Therefore, the converter The metal component remaining in the (100) does not adhere to the area around the furnace bulb (110). In other words, the exhaust gas forms a stable discharge flow in the condition that no current is attached to the furnace.

Accordingly, an electromagnetic field is formed as shown in FIG. 1B, that is, the N pole is formed at the upper end of the electromagnet 220, and the direction of the force formed by the electromagnetic field is formed along the outside of the furnace ball 111. That is, the flow of the magnetic force line is formed along the outer direction of the furnace hole 111.

The exhaust gas containing a metal component is exhausted to the outside of the furnace opening 111 in the receiving space of the converter 100, at this time, the metal component is forcibly guided to the outside of the furnace opening 111 along the flow of the electromagnetic force line to be discharged. I can.

Gas supply control unit 300

FIG. 2 is a view showing a device for preventing attachment of a converter furnace equipped with a gas supply control unit according to the present invention. 3 is a view showing the configuration of a gas supply control unit according to the present invention.

2 and 3, the gas supply control unit 300 according to the present invention is provided in the furnace nozzle 111, and controls the gas component composition of the exhaust gas to form a preset reference gas component composition to achieve a reference gas supply amount. Do it.

The gas supply control unit 300 according to the present invention includes a collection unit 310 that collects exhaust gas, a measurement unit 320 that measures a gas component of the collected exhaust gas, and the measured gas component is preset. Consisting of a composition variable part 330 for adjusting a reference gas composition, and a gas supply part 340 for supplying a plurality of gases to the inner space of the furnace hole 111 through the furnace hole 111 by forming the reference gas composition do.

The gas supply unit 340 supplies the plurality of gases to achieve the reference gas supply amount.

In addition, the gas supply unit 340 includes unit gas supply units 341 supplying a plurality of the gases, and a gas supply pipe 342 disposed inside the mouth ring 130.

The gas supply pipe 342 receives a plurality of the gases from the plurality of unit gas suppliers 341 through one end thereof, and receives the plurality of gases supplied through the other end exposed through the inner circumference of the mouth ring 130. It is supplied to the inner region of the furnace hole 111.

Here, the unit gas suppliers 341 may control the plurality of gases to form the reference gas composition and to achieve the reference gas supply amount.

4 is a view showing a device for preventing attachment of a converter furnace to which another example of the discharge induction unit according to the present invention is applied. 5 is a view showing a device for preventing adhesion of a converter furnace equipped with a gas supply control unit according to the present invention.

4 and 5, the discharge induction part 400 according to the present invention includes a permanent magnet 410 disposed inside the furnace shell 120 described above.

Here, an S pole is formed on one surface of the permanent magnet 410 and an N pole is formed on the other surface.

The other surface of the permanent magnet 410 on which the N pole is formed is disposed to face the receiving space of the converter 100.

According to the configuration, a magnetic field is formed inside the furnace ball 111, and a force generated by the formation of the magnetic field is formed along the outside of the furnace ball 111 inside the converter.

The exhaust gas may be guided to be discharged to the outside of the furnace hole 111 by the magnetic force as described above.

Through the above configuration, it will be described the operation of the current adhesion prevention facility according to the present invention.

Referring to FIGS. 1A to 3, as a large amount of oxygen is supplied to the converter 100 through a lance, exhaust gas of the CO component is generated.

In addition, metal components such as slag and iron are present in the receiving space of the converter 100. The exhaust gas generated at this time, slag in the converter, and iron are combined to generate now.

At this time, the current provider 220 provides a current set to the electromagnetic induction coil 210.

The electromagnetic induction coil 210 is magnetized and an electromagnetic field is formed. As for the polarity, the upper part forms the N pole and the lower part forms the S pole.

Therefore, the direction of the force is formed along the outside of the furnace (111).

Accordingly, the metal component remaining in the receiving space of the converter body 110 is induced to be discharged to the outside of the furnace hole 111 without being adhered to the inner circumference and the periphery of the furnace hole 111.

Accordingly, as the exhaust gas generated in the accommodation space is not blocked, the flow velocity of the exhaust gas may be increased more than a certain level.

In addition, in the present invention, by variably providing current through the current providing unit 220, the strength of electromagnetic force may be variably formed. Therefore, it is possible to increase the force that pushes the metal component outward.

Accordingly, the exhaust gas is induced not to be directly attached to the furnace by the magnetic field. Also, if the strength of the magnetic field is increased, the flow velocity in the furnace mouth becomes faster and the current does not stick.

Of course, even when the permanent magnet 400 shown in FIG. 4 is used, the magnetic force line forms a flow along the outer direction of the furnace as the N pole is disposed toward the inside of the furnace as described above. Stable flue gas flow can be induced so that no current is attached to the furnace.

Meanwhile, the exhaust gas exhausted through the furnace opening 111 may be collected by a predetermined amount through the collecting unit 310.

Then, the gas component of the exhaust gas collected through the measurement unit 320 is measured. For example, CO, O2, N2, H are measured.

The composition variable unit 330 adjusts the measured gas component to form the preset reference gas composition.

The gas supply unit 340 may form the reference gas composition and supply a plurality of gases to the inner space of the furnace opening 111 through the furnace opening 111.

According to the above configuration and operation, the embodiment according to the present invention can improve productivity by not accumulating currents in the furnace.

In addition, the embodiment according to the present invention can prevent abnormal reactions such as explosion due to stagnation of exhaust gas in the converter.

In addition, the present invention may improve the factory environment by preventing exhaust gas from being discharged out of the dust collecting facility (Skirt) through stable exhaust gas induction.

On the other hand, although not shown in the drawings, the magnet according to the present invention described above may be disposed to be elevating in the peripheral area of the furnace.

The magnet may be connected to a wire disposed in an upper region of the furnace, and the wire may be connected to be wound by a winder for winding the wire.

Through this configuration, the lifting position of the magnet can be adjusted. The position of the magnetic field formation can be variably adjusted according to the lifting position.

In addition, the magnet can be raised and lowered at a constant speed. Accordingly, there is an advantage that the position of the magnet may be changed and disposed in consideration of the position where the magnetic field is formed by changing the position where the magnetic field is formed.

As described above, specific embodiments of the apparatus for preventing adhesion of the converter furnace of the present invention have been described, but it is obvious that various implementation modifications are possible within the limits not departing from the scope of the present invention.

Therefore, the scope of the present invention is limited to the described embodiments and should not be transmitted, and should be determined by the claims to be described later, as well as those equivalent to the claims.

That is, it should be understood that the above-described embodiments are illustrative in all respects and not limiting, and the scope of the present invention is indicated by the claims to be described later rather than the detailed description, and the meaning and scope of the claims and All changes or modified forms derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

100: converter
110: converter body
111: Nogu
120: Nogu Cheolpi
130: mouse ring
200: discharge induction part
210: electromagnetic induction coil
220: electromagnet
230: current provider
300: gas supply control unit
310: collection unit
320: measuring unit
330: composition variable part
340: gas supply
341: unit gas supply
342: gas supply pipe

Claims (6)

A converter forming a furnace and having an accommodation space in which molten steel is accommodated therein;
It includes a magnet disposed in a peripheral area of the furnace, and a line of magnetic force formed through the magnet is formed along the outer direction of the furnace to induce the metal components remaining in the accommodation space to be discharged to the outside of the furnace, and the A discharge inducing part for preventing metal components from sticking to the area around the furnace; And,
A gas supply control unit configured to supply a plurality of gases through the gas supply unit such that a gas component composition of the exhaust gas is formed with a predetermined reference gas component composition to form a reference gas supply amount, and includes a gas supply unit disposed in the furnace opening;
The above converter,
A converter body forming the furnace at an upper end and in which the accommodation space is formed,
A furnace iron shell formed on an upper end of the converter body to surround the furnace and having a cooling water passage therein,
Including a mouse ring disposed on the upper end of the furnace door to surround the furnace,
The discharge induction part is installed inside the furnace iron shell,
A cooling coil is disposed in the vicinity of the inner periphery of the furnace shell,
The cooling coil is cooled to a predetermined temperature through a current provided from a separate current device to further cool the exhaust gas,
A facility to prevent adhesion of the converter furnace.
The method of claim 1,
Cooling water is accommodated in the furnace shell, and the cooling water is circulated through a separate circulation device,
The inner periphery of the nogu iron skin forms a slope extending from the top to the bottom,
Guide grooves along the top and bottom are formed in the inner circumference of the inclined furnace shell, and the guide grooves guide the discharge of the exhaust gas,
A facility to prevent adhesion of the converter furnace.
The method of claim 2,
The discharge induction part,
An electromagnetic induction coil disposed inside the furnace iron shell to surround the furnace furnace;
A current providing device configured to form a magnetic field by providing a current to the electromagnetic induction coil to magnetize the electromagnetic induction coil to become the magnet,
The force generated by the magnetic field is,
It is formed along the outside of the furnace,
The current provider variably provides the current to the electromagnetic induction coil to variably form an electromagnetic force intensity,
A facility to prevent adhesion of the converter furnace.
The method of claim 2,
The discharge induction part,
Including a permanent magnet disposed inside the furnace iron shell,
An S pole is formed on one side of the permanent magnet, and an N pole is formed on the other side,
The other surface portion of the permanent magnet on which the N pole is formed,
It is disposed to face the receiving space of the converter,
The permanent magnet is the magnet,
A facility to prevent adhesion of the converter furnace.
The method of claim 2,
The gas supply control unit,
A collection unit for collecting the exhaust gas,
A measuring unit for measuring a gas component of the collected exhaust gas,
A composition variable unit for adjusting the measured gas component to achieve the preset reference gas composition;
Comprising the gas supply unit for supplying the inner space of the furnace through the furnace by forming the reference gas composition of the plurality of gases,
The gas supply unit,
To supply the gas forming a plurality to achieve the reference gas supply amount,
A facility to prevent adhesion of the converter furnace.
The method of claim 5,
The gas supply unit,
Unit gas suppliers supplying a plurality of the gases,
It is disposed inside the mouth ring, a plurality of the gas is supplied from the plurality of unit gas supply through one end, and a plurality of the gas supplied through the other end exposed through the inner periphery of the mouth ring is the inner area of the furnace A gas supply pipe supplied to the
The unit gas suppliers,
Controlling the plurality of gases to form the reference gas composition and to achieve the reference gas supply amount,
A facility to prevent adhesion of the converter furnace.

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