KR101567188B1 - A cooling device for a electrode of a electric furnace and the method for controlling operation thereof - Google Patents

Abstract

[0001] The present invention relates to an electric furnace electrode water-cooling apparatus, which comprises a cooling water injection passage for injecting cooling water into an electrode of an electric furnace, a cooling water transfer passage for supplying cooling water to the cooling water injection passage and a heat radiation member It is possible to cool the cooling water injection pipe to prevent deformation due to high temperature, to reduce the cost of replacing the parts, and to prevent the cooling performance from being deteriorated by the nozzle clogging phenomenon.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a water-cooling apparatus for an electric furnace and a method of controlling the same,

The present invention relates to an electric furnace electrode water-cooling apparatus and its operation control method, and more particularly, to an electric furnace electrode water-cooling apparatus for cooling an electrode of an electric furnace by injecting cooling water.

Generally, an electric furnace is an apparatus for melting scrap iron by arc heat generated by an electrode. The electric furnace is equipped with an electrode cooling device to prevent the electrodes from being heated and oxidized by the arc heat to shorten the service life. The electrode accelerates the oxidation in proportion to the temperature, increases the power consumption by the oxidation, and the refractory is eroded due to the electric arc concentrating phenomenon.

An electrode water cooling apparatus using cooling water has an annular cooling water spraying tube around the electrode to cool the electrode by spraying cooling water to the outer circumferential surface of the electrode.

Since the cooling water spraying pipe is provided adjacent to the periphery of the electrode, there is a problem that the electrode is deformed or oxidized due to the high temperature of the electrode during the operation of the electric furnace, thereby shortening the service life.

In this case, when the cooling water injection pipe is made of one member, the cooling water injection pipe is deformed or damaged due to high temperature, .

Korean Patent Laid-Open Publication No. 2012-0118263 discloses a technique for separating and assembling two injection pipes and assembling them so that only the damaged one can be replaced when the injection pipe is damaged. However, this does not solve the fundamental problem of deformation of the cooling water injection pipe, which reduces the cost of replacement of the injection pipe by the deformation and oxidation.

A device for cooling the cooling water injection pipe itself for preventing deformation and oxidation of the cooling water injection pipe due to high temperature has not been developed at present.

On the other hand, a plurality of injection holes or injection nozzles are provided at predetermined intervals along the circumferential direction of the electrodes in the cooling water injection tube.

In the case of an electrode water cooling apparatus in which only a spray hole is formed in a spray pipe without a separate nozzle, it is difficult to control the spray direction of the cooling water, so that the cooling water is not uniformly sprayed.

Even in the case of the electrode water cooling apparatus having the injection nozzle in the conventional cooling water injection tube, since the injection nozzle is fixedly and integrally fixed to the injection pipe so as to replace the injection nozzle, it is necessary to replace the entire injection pipe, there was.

In addition, the conventional injection nozzle is easily clogged by the dust generated when the scrap iron is inserted into the electric furnace, and the cooling water discharge performance is deteriorated, thereby deteriorating the electrode cooling performance. If dust is not removed by manual operation at the time of clogging of the injection nozzle, the injection nozzle is permanently clogged, and the entire cooling water injection tube must be replaced.

The present invention has been made in order to solve the problems of the conventional electric furnace electrode water cooling apparatus and its operation control method as described above. It is possible to cool the cooling water spray pipe to prevent deformation and oxidation due to high temperature, And it is an object of the present invention to provide an electric furnace electrode water-cooling apparatus and its operation control method which can reduce the replacement cost of components and prevent the injection nozzle from being clogged by the dust and deteriorate the spraying performance.

In order to achieve the above object, an electric furnace electrode water cooling apparatus according to the present invention includes a cooling water injection channel for injecting cooling water into electrodes of an electric furnace, a cooling water transfer channel for supplying cooling water to the cooling water injection channel, And a heat dissipating member provided to be in contact with the cooling water transfer path to discharge heat of the cooling water transfer path.

In the electric furnace electrode water cooling apparatus according to an embodiment of the present invention, the cooling water injection path may be formed in an annular shape so as to surround the periphery of the electrode.

In the electric furnace electrode water-cooling apparatus according to an embodiment of the present invention, the heat dissipation member is provided so as to be in contact with the cooling water injection path.

In the electric furnace electrode water cooling apparatus according to an embodiment of the present invention, the heat dissipating member may be formed in a plate shape.

In the electric furnace electrode water-cooling apparatus according to an embodiment of the present invention, the cooling water transfer path and the cooling water injection path are formed with openings at one side thereof, and the heat dissipating member covers the openings of the cooling water transfer path and the cooling water injection path, Shape.

In the electric furnace electrode water cooling apparatus according to an embodiment of the present invention, the heat dissipation member may include a main heat dissipation plate covering an opening portion of the cooling water transfer path, and a sub heat dissipation plate covering the opening portion of the cooling water injection path.

In the electric furnace electrode water cooling apparatus according to an embodiment of the present invention, the cooling water transfer path and the cooling water injection path may have an arc shape, a V shape, and a C shape in cross section.

In the electric furnace electrode water cooling apparatus according to an embodiment of the present invention, the cooling water conveying passage may be formed in a meandering shape.

In the electric furnace electrode water cooling apparatus according to an embodiment of the present invention, the cooling water conveyance passage includes a main conveyance passage and a plurality of sub conveyance passages branched from the main conveyance passage and supplying cooling water to the cooling water injection passage .

In the electric furnace electrode water cooling apparatus according to an embodiment of the present invention, the electric furnace may further include an injection nozzle detachably installed at one side of the cooling water injection path and injecting cooling water into the electrode.

In the electric furnace electrode water-cooling apparatus according to an embodiment of the present invention, the injection nozzle may include a nozzle body portion fixedly coupled to one side of the cooling water injection path, and a nozzle portion detachably coupled to the nozzle body portion. have.

In the electric furnace electrode water-cooling apparatus according to an embodiment of the present invention, an air injection unit that supplies air to the injection nozzle through the cooling water transfer path and the cooling water injection path to discharge the air, It is also possible to include a control unit for selectively supplying cooling water or air.

In the electric furnace electrode water cooling apparatus according to an embodiment of the present invention, the air injection unit may include an air supply source for supplying compressed air, and an air supply flow path for supplying air from the air supply source to the cooling water transfer path It is possible.

In the electric furnace electrode water-cooling apparatus according to an embodiment of the present invention, the control unit includes an air opening / closing valve for opening / closing the air supply passage, and a cooling water supply passage for supplying cooling water from the cooling water supply source to the cooling water transfer passage A cooling water opening / closing valve.

In the electric furnace electrode water cooling apparatus according to an embodiment of the present invention, the control unit may further include a controller for applying an optional opening / closing signal to the air opening / closing valve or the cooling water opening / closing valve.

The control unit may measure the pressure of the fluid supplied to the cooling water transfer path and determine whether the injection nozzle is clogged by comparing the pressure of the fluid with the normal pressure.

The control unit may determine that the injection nozzle is clogged when the measured pressure is higher than the normal pressure and apply a signal to open the air on / off valve so that air can be injected into the injection nozzle.

The electric furnace electrode water-cooling apparatus according to an embodiment of the present invention may further include a heat exchange unit for cooling the heat dissipation member.

According to an aspect of the present invention, there is provided an operation control method for an electric furnace electrode water cooling apparatus including a cooling water injection channel for injecting cooling water into electrodes of an electric furnace, a cooling water supply channel for supplying cooling water to the cooling water injection channel, And an air supply flow path for supplying air to the cooling water supply flow path, the method comprising the steps of: operating the electric furnace during the operation of the electric furnace; The cooling water supply passage is opened so that the cooling water is supplied to the cooling water injection passage and the air supply passage is closed and the air supply passage is opened so that air is injected through the cooling water injection passage when the electric furnace is in operation And closes the cooling water supply passage, and when the electric furnace is stopped, The cooling water supply passage and the air supply passage are closed.

According to an aspect of the present invention, there is provided an operation control method for an electric furnace electrode water cooling apparatus including a cooling water injection channel for injecting cooling water into electrodes of an electric furnace, a cooling water supply channel for supplying cooling water to the cooling water injection channel, And an air supply passage for supplying air to the cooling water supply passage, the operation control method comprising the steps of: discharging the cooling water from the cooling water discharge channel; The pressure of the fluid supplied through the transfer passage is measured and compared with the normal pressure to determine whether the injection nozzle is blocked. If the measured pressure is higher than the normal pressure, it is determined that the injection nozzle is clogged and air is injected into the injection nozzle The air supply passage is opened and the cooling water supply passage is closed .

The features and advantages of the present invention will become more apparent from the following detailed description based on the accompanying drawings.

As described above, according to the electric furnace electrode water-cooling apparatus and the operation control method of the electric furnace according to the present invention, it is possible to cool the cooling water injection tube to prevent deformation and oxidation due to high temperature and to improve cooling performance, It is possible to prolong the lifetime and reduce the power consumption, and prevent the arc furnace from concentrating in the arc furnace due to the oxidation phenomenon, thereby preventing the erosion of the refractory.

It is possible to detachably connect the spray nozzles to the cooling water spray tubes and individually replace the spray nozzles, thereby reducing the replacement cost of the parts when the life of the spray nozzles is limited.

It is possible to prevent the clogging of the injection nozzle by the high-pressure air by using the time when the operation is stopped, thereby preventing the injection nozzle from clogging due to the dust, so that the injection nozzle can be used semi-permanently .

FIG. 1 is a schematic cross-sectional view showing an installation state of an electric furnace electrode water cooling apparatus according to an embodiment of the present invention,
FIG. 2 is a side view of the electric furnace electrode water cooling apparatus shown in FIG. 1,
FIG. 3 is a schematic cross-sectional view cut along line AA of FIG. 2;
4 is an exploded sectional view showing the electric furnace electrode water cooling apparatus shown in FIG. 1,
5 is an enlarged view of a portion "B" in Fig. 3,
6 is a side view showing an electric furnace electrode water cooling apparatus according to another embodiment of the present invention.
7 is a schematic cross-sectional view showing an electric furnace electrode water cooling apparatus according to another embodiment of the present invention,
8 is a flowchart illustrating an operation control method of an electric furnace electrode water cooling apparatus according to an embodiment of the present invention.

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

1, a plurality of electrodes 2 are fixedly coupled to a top end of a furnace body 1 that houses scrap iron by a support member 3, and the electrode water cooling apparatus of the present invention is mounted around the electrodes 2 Respectively.

1 to 7, an electric furnace electrode water cooling apparatus according to an embodiment of the present invention includes a cooling water injection path 10 for injecting cooling water into an electrode 2 of an electric furnace, A cooling water transfer passage 20 for supplying cooling water, a heat dissipating member 30 for radiating heat of the cooling water transfer passage 20, a cooling water transfer passage 20 and a cooling water injection passage 10, And a control unit for selectively supplying cooling water or air to the cooling water transfer passage 20 and the cooling water injection passage 10. [

The coolant injection path 10 is formed in an annular shape so as to surround the periphery of the electrode 2.

The cooling water transfer passage 20 communicates with the cooling water injection passage 10 and transfers the cooling water supplied from the cooling water supply source 41 through the cooling water supply passage 42 to the cooling water injection passage 10.

The cooling water conveyance passage 20 includes a main conveyance passage 21 and a sub conveyance passage 22 branched from the main conveyance passage 21.

2, the main transfer passage 21 is connected to the cooling water supply passage 42, and the sub-transfer passage 22 is branched from the main transfer passage 21 into a plurality of channels, And supplies the cooling water to the cooling water injection path (10). The sub conveying passage 22 is formed in a bent shape and two sub conveying passages 22 are provided symmetrically with respect to the main conveying passage 21.

As shown in FIG. 6, the sub conveying passage 22 'branched from the main conveying passage 21' is formed in a substantially 'C' shape.

As described above, the main transfer paths 21 and 21 'and the sub transfer paths 22 and 22' are formed in a meandering shape that is bent in various shapes, thereby maximizing the heat exchange area with the heat radiation member 30.

The heat dissipating member 30 is formed in a plate shape and the cooling water transfer passage 20 and the cooling water injection passage 10 are coupled to one side of the heat dissipating member 30.

Openings 23 and 11 are formed at one side of the cooling water transfer path 20 and the cooling water injection path 10, respectively. That is, the cooling water transfer passage 20 and the cooling water injection passage 10 are formed in a shape having a single cross-sectional shape. 5, the cooling water transfer passage 20 and the cooling water injection passage 10 may be formed into a V shape or a C shape or an arc shape, And is formed in a pipe shape together with the heat dissipating member (30), all are included in the scope of the present invention.

The heat dissipating member 30 is formed in a plate shape and covers the openings 23 and 11 of the cooling water transfer passage 20 and the cooling water injection passage 10. Accordingly, the heat dissipating member 30, the cooling water transfer passage 20, and the cooling water injection passage 10 are formed into a tubular shape as a whole.

The heat dissipating member 30 includes a main heat dissipating plate 31 covering the opening 23 of the cooling water transfer path 20 and a sub heat sink 32 covering the opening 11 of the cooling water injection path 10 .

The main heat radiating plate 31 and the sub heat sink 32 are formed to be larger than the cooling water transfer path 20 and the cooling water injection path 10 to maximize the heat radiation area.

The sub heat sink 32 is formed in an annular shape similar to the cooling water injection path 10 and includes an electrode accommodating portion 33.

The heat dissipating member 30 is disposed in contact with the cooling water transfer path 20 and the cooling water injection path 10 to exchange heat with each other. 5, the tips of the main heat sinks 31 and the sub heat sinks 32 having a V-shaped cross section are in contact with one side of the cooling water transfer passage 20 and the cooling water injection passage 10, Welded and joined together. Accordingly, the heat generated in the cooling water transfer path 20 and the cooling water injection path 10 is transferred to the heat dissipating member 30. The cooling water injection path 10, the cooling water transfer path 20, and the radiation member 30 are made of a metal.

A plurality of spray nozzles 15 are provided at one side of the cooling water spray passage 10 at predetermined intervals along the longitudinal direction thereof.

The injection nozzle (15) is detachably provided and injects cooling water into the electrode (2)

The injection nozzle 15 includes a nozzle body portion 16 fixedly coupled to one side of the cooling water injection path and a nozzle portion 17 detachably coupled to the nozzle body portion 16. Accordingly, when the nozzle unit 17 is deformed or damaged, the nozzle unit body 16 can be separated from the nozzle body unit 16 and can be easily replaced.

Meanwhile, the nozzle body 16 may be pivotally coupled to one side of the cooling water injection path (not shown). As described above, when the nozzle body 16 is pivotally coupled to the cooling water injection path 10 without being fixedly coupled to the cooling water injection path 10, the injection angle can be adjusted.

The air injection unit includes an air supply source 51 for supplying compressed air and an air supply passage 52 for supplying air from the air supply source 51 to the cooling water transfer passage 20.

The control unit includes an air opening / closing valve 53 for opening and closing the air supply passage 52, a cooling water opening / closing valve 53 for opening / closing a cooling water supply passage 42 for supplying cooling water from the cooling water supply source 41 to the cooling water transfer passage 20, A control unit for applying a selective opening and closing signal to the air opening / closing valve 53 and the cooling water opening / closing valve 43, a pressure detecting unit 60 for measuring the pressure of the fluid discharged through the injection nozzle 15, (70).

The air on / off valve (53) is provided in the air supply passage (52) and receives the opening / closing signal from the controller (70) to cut off the supply of air.

The cooling water opening / closing valve 43 is provided in the cooling water supply passage 42 and receives the opening / closing signal from the controller 70 to block the supply of the cooling water.

The pressure detecting unit 60 is provided in the cooling water transfer path 20 to indirectly detect the discharge pressure of the fluid by measuring the fluid pressure on the cooling water transfer path 20. The fluid measured by the pressure detecting unit 60 is cooling water supplied from the cooling water supply passage 42 or air supplied from the air supply passage 52.

When the ejection nozzles 15 are clogged under the same condition of the output from the coolant supply source 41 or the air supply source 51 and the unsteady discharge pressure is compared with the unsteady discharge pressure, .

Therefore, when the cooling water is injected during the operation of the electric furnace, the cooling water pressure on the cooling water conveyance passage 20 is measured and compared with the normal pressure, so that the clogging state of the injection nozzle 15 can be determined.

The control unit 70 stores the normal pressure P _c in which the injection nozzle 15 is not blocked and receives the fluid pressure value P _a detected from the pressure detecting unit 60, (P _c ). To this end, the control unit 70 includes a memory unit and an operation unit.

The control unit 70 determines that the injection nozzle 15 is blocked if the calculation result measurement pressure P _a is higher than the normal pressure P _c .

The control unit 70 sends a pressure detection signal to the pressure detection unit 60 to detect the pressure of cooling water or air and is electrically connected to the air on / off valve 53 and the cooling water on / off valve 43, .

When the injection nozzle 15 is determined to be clogged, the controller 70 applies a closing signal to the cooling water opening / closing valve 43 and applies an opening signal to the air opening / closing valve 53.

On the other hand, in a state where the operation of the electric furnace is stopped, the supply of the cooling water to the injection nozzle 15 is cut off, and the air pressure is measured while air is supplied to determine whether the injection nozzle 15 is blocked.

For example, air is supplied from the air supply source 51 to the cooling water transfer passage 20 in a normal state in which the injection nozzle 15 is not blocked, and the pressure is measured and stored in the controller 70.

Thereafter, when the operation of the electric furnace is stopped and the supply of the cooling water is stopped, air is supplied to the injection nozzle 15 to measure the air pressure. At this time, the controller 70 compares the stored normal pressure with the measured pressure, and determines that the nozzle is blocked if the normal pressure is greater.

If it is determined that the nozzle is clogged, the air is continuously supplied to remove the foreign material which is the source of the clogging of the nozzle. When the measured pressure becomes equal to or smaller than the normal pressure, the controller 70 determines that the nozzle clogged state has been solved and applies a closing signal to the air on / off valve 53 to stop the air supply. The control unit 70 may be configured to apply a close signal according to the elapse of the set time.

The heat dissipating member (30) is cooled by a heat exchange unit.

3 includes an internal heat exchanger 81 that is in surface contact with one side surface of the heat dissipating member 30 and an external heat exchanger 82 that circulates and cools the circulating water of the internal heat exchanger 81 .

The internal heat exchanger (81) is filled with circulating water and circulated to the external heat exchanger (82) to transfer heat.

The external heat exchanger (82) is provided at a predetermined distance from the internal heat exchanger (81) to cool the circulating water circulating without being affected by the high temperature of the electrode (2).

The heat exchange unit shown in Fig. 7 includes a cooling fin 91 and a cooling fan 92.

The cooling fin 91 is formed of a metal material for heat dissipation, and is fixedly coupled to one side of the heat dissipating member 30 in a surface contact manner.

The heat generated from the cooling fins 91 is released to the atmosphere by the cooling fan 92.

2 and 8, an operation control method of an electric furnace electrode water cooling apparatus according to an embodiment of the present invention will be described.

First, when the injection nozzle 15 is in a non-clogged state, the cooling water pressure on the cooling water conveyance passage 20 is measured through the pressure detecting unit 60 when the electric furnace is in operation and is set to a normal pressure value P _c do. That is, the pressure of the cooling water is measured at the time of initial operation of the electric furnace or immediately after the parts of the injection nozzle 15 are replaced and set to the normal pressure (P _c ).

Then, it is determined whether or not the electric furnace is operated (S10). When the electric furnace is in operation, the cooling water supply / discharge flow path 42 is opened by opening the cooling water opening / closing valve 43 so that the cooling water is supplied to the cooling water injection path 10 The air supply passage 52 is closed (S11). At this time, the measured water pressure (P _a), on said cooling water feed channel 20 through the pressure detector (60) (S12).

Since when the operation of the electric furnace is stopped, measuring the pressure (P _a) and normal pressure (P _c) to compare and (S20) measuring the pressure (P _a), the normal pressure (P _c) is greater than the cooling water supply passage 42, the And at the same time, the air supply passage 52 is opened (S30).

Here, the operation standby state and the idle state are classified according to the operation stop time (t _a ) of the electric furnace. The operation stop time t _a is measured and compared with the preset time t _{c in step} S40. If the operation stop time t _a is less than the set time t _c , It is determined that the stopping time t _a is in _a rest state when the set time t _c has elapsed.

When the electric furnace is in the operation standby state, the open state of the air supply passage (52) is maintained and the air is continuously injected into the injection nozzle (15).

When the electric furnace is in a rest state, the cooling water supply passage 42 and the air supply passage 52 are closed to stop the injection of air and cooling water (S50).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is obvious that the modification or the modification is possible by the person.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

10: Cooling water injection flow path 11:
15: injection nozzle 16: nozzle body
17: nozzle unit 20: cooling water conveying passage
21 and 21 ': main transfer paths 22 and 22': sub-
23: opening portion 30: heat dissipating member
31: main heat sink 32: sub heat sink
33: electrode housing part 41: cooling water supply source
42: cooling water supply passage 43: cooling water opening / closing valve
51: air supply source 52: air supply flow path
53: air opening / closing valve 60: pressure detecting section
70: control unit 81: internal heat exchanger
82: external heat exchanger 91: cooling pin
92: Cooling fan

Claims (23)

A cooling water spraying passage formed in an annular shape so as to surround the periphery of the electrode and having an opening formed at one side thereof and spraying cooling water to electrodes of the electric furnace;
A cooling water transfer passage for supplying cooling water to the cooling water injection path; And
And a sub heat sink for contacting the cooling water transfer path and a sub heat sink for contacting the cooling water injection path. The cooling water transfer path and the cooling water injection path are formed as a whole, covering the openings of the cooling water transfer path and the cooling water injection path, Like heat dissipating member which emits heat of a plate-like shape; And
A spray nozzle detachably attached to one side of the cooling water spray path and spraying cooling water to the electrode;
And an electric furnace. delete delete delete delete delete The method according to claim 1,
Wherein the cooling water transfer passage and the cooling water injection passage have an arc-shaped cross section. The method according to claim 1,
Wherein the cooling water transfer path and the cooling water injection path have a V-shaped cross section. The method according to claim 1,
Wherein the cooling water transfer path and the cooling water injection path are formed in a U-shaped cross-section. 2. The water treatment system according to claim 1,
And is formed by being bent in a labyrinth shape. 11. The water treatment system according to claim 10,
A main transfer path; And
And a plurality of sub conveyance flow paths branched from the main conveyance flow passage and supplying cooling water to the cooling water injection flow path. delete The ink jet recording head according to claim 1,
A nozzle body fixedly coupled to one side of the cooling water injection path; And
And a nozzle part detachably coupled to the nozzle body part. 14. The method of claim 13,
An air injection unit that supplies air to the injection nozzle through the cooling water transfer path and the cooling water injection path to discharge the air; And
And a control unit for selectively supplying cooling water or air to the cooling water transfer path and the cooling water injection path. 15. The air conditioner according to claim 14,
An air supply source for supplying compressed air; And
And an air supply passage for supplying air from the air supply source to the cooling water transfer passage. 15. The apparatus of claim 14,
An air opening / closing valve for opening / closing the air supply passage; And
And a cooling water opening / closing valve for opening / closing a cooling water supply passage for supplying cooling water from the cooling water supply source to the cooling water transfer passage. 17. The apparatus of claim 16,
And a controller for applying an optional opening / closing signal to the air opening / closing valve or the cooling water opening / closing valve. 18. The apparatus of claim 17,
Wherein the pressure of the fluid supplied to the cooling water transfer path is measured and compared with a normal pressure to determine whether the injection nozzle is blocked or not. 18. The apparatus of claim 17,
Wherein when the measured pressure of the fluid supplied to the cooling water transfer path is higher than a normal pressure, the controller determines that the injection nozzle is clogged and applies a signal to open the air opening / closing valve so that air can be injected into the injection nozzle Electric furnace electrode water cooling system. The method according to claim 1,
And a heat exchange unit for cooling the heat dissipation member. delete delete delete

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