KR101130995B1 - Cooling apparatus integrated graphite electrode holder and electric furnace using the same - Google Patents

Abstract

The present invention relates to a graphite electrode holder integrated cooling device and an electric furnace using the same, a holding member for holding a graphite electrode, a flow rate control unit formed with a plurality of injection nozzles for adjusting the cooling water flow rate and the holding member and the graphite electrode Provided is a graphite electrode holder integrated cooling device including a plurality of vertical flow paths formed in a holding member in the contact area and an electric furnace using the same. As a result, the graphite electrode can be effectively cooled by allowing the cooling water to flow through the graphite electrode regardless of disturbances such as vibration generated during operation, thereby preventing the graphite electrode from being worn out and broken, and installing the cooling device once. Since it can be used semi-permanently, it can solve the problem of downtime for cooling device replacement, reduce material cost, replacement and repair cost, and reduce cost through electrode loss and wear prevention.

Graphite electrode, cooling device, cooling flow path, flow control part, cooling water pipe, molten steel, mini mill DC electric furnace

Description

Cooling apparatus integrated graphite electrode holder and electric furnace using the same             

1 is a cross-sectional view illustrating a graphite electrode holder and a cooling device according to the prior art.

2 is a cross-sectional view of the graphite electrode holder integrated cooling device according to the present invention.

3 is a cross-sectional view of the graphite rod assembled in the graphite electrode holder integrated cooling device according to the present invention.

4 is a plan view of the graphite electrode holder integrated cooling device according to the present invention.

5 is a view for explaining an electric furnace including a graphite electrode holder integrated cooling device according to the present invention.

<Explanation of symbols for the main parts of the drawings>

10, 200: graphite electrode rod 20, 110: holding member

25: holder flow path 30, 160, 170: cooling water piping

40: pipe 45: hole

50: clamp 120: center channel                 

130: flow rate control unit 135: nozzle

140: vertical flow path 150: power supply pipe

172: Insulator 174: Insulation Hose

100: cooling device 300: lower electrode rod

400: Lance 500: Body

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a graphite electrode holder integrated cooling device and an electric furnace using the same. In particular, a graphite electrode rod that can protect the graphite electrode from radiation generated during operation of a mini mill DC electric furnace, and fly ash generated during melting, scrap metal melting, and oxygen injection. It relates to a holder integrated cooling device and an electric furnace using the same.

The conventional mini mill DC electric furnace includes a graphite electrode at the top and an electrode at the bottom. At this time, the upper graphite electrode is connected to the negative electrode, the lower electrode is connected to the positive electrode, supplying a current to the electrode to dissolve the scrap metal between the electrodes to produce molten steel.

The mini-mill's direct current furnace uses more than 2000 times of the lower electrode compared to the alternating current method, whereas the upper graphite electrode has a high wear rate, leading to a breakdown in the tip of the graphite electrode due to increased production cost and scrap metal. Problem occurs. The lifetime of this graphite electrode may be due to installation conditions and cooling device structure, and may occur when residual coolant that is adaptable to radiant heat inside the pipe is stagnant.

1 is a cross-sectional view illustrating a graphite electrode holder and a cooling device according to the prior art.

Referring to FIG. 1, a conventional graphite electrode holder includes a holder channel 25 formed therein, a holding member 20 for holding the graphite electrode rod 10, and a coolant pipe 30 into which coolant is injected. .

The cooling apparatus includes a steel pipe 40 having a plurality of holes 45 formed therein, and a clamp 50 for fixing the steel pipe 40 to the lower portion of the holding member 20. After the steel pipe 40 is manufactured by bending, the clamp 50 is fixed to the holding member 20. At this time, the hole 45 is processed by using a drill inside the pipe so that the coolant comes out. Here, the pipe 40 may further include a separate pipe for injecting a predetermined cooling water.

In this way, the cooling device is installed at the lower end of the holding member 20 fixing the electrode 10, and the service life is extended from about 4 hours due to the radiant heat generated from the furnace body and the molten steel scattered when molten oxygen is generated. In about 60 hours, melting and breakage occur in the cooling device during operation. This leads to the problem that the operation must be stopped and exchanged. Of course, at this time, due to the high temperature there is a difficult problem of exchange. In addition, there is a problem that the cooling water is not properly sprayed on the graphite rod due to the vibration generated during the operation.

Therefore, the present invention can be protected from radiant heat generated during operation and by-products generated from flame, scrap metal melting and oxygen blowing to solve the above problems, can prevent deformation of the melt, and the cooling water can be An object of the present invention is to provide a graphite electrode holder integrated cooling device and an electric furnace using the same.

A plurality of vertical flow paths formed in the holding member for holding the graphite electrode rod according to the present invention, the flow rate control unit formed with a plurality of injection nozzles for adjusting the cooling water flow rate and the holding member in the region where the holding member and the graphite electrode contact It provides a graphite electrode holder integrated cooling device comprising.

Here, a central flow path formed in the holding member, a power supply pipe for supplying predetermined electric power to the graphite electrode rod, a central cooling water pipe for supplying predetermined cooling water to the central flow path, and a predetermined cooling water in the flow rate control unit are provided. It may further include an upper cooling water pipe for supplying.

At this time, the upper cooling water pipe, it is preferable to include a predetermined pipe, an insulator for the pipe fixing part for preventing damage by the magnetic field, and an insulating hose for ensuring the flexibility of the pipe connection and easy disassembly and assembly of the line. In addition, the flow rate control part is formed integrally with the holding member in the upper region of the holding member, or is mounted through a separate production, it is effective to have a predetermined slope.

Further, any one of claims 1 to 3 for holding and cooling the body portion having a predetermined internal space, the graphite electrode rod penetrating from the upper portion of the body portion to a predetermined space inside the body portion, and the graphite electrode rod on the upper portion of the body portion Provided is an electric furnace including a graphite electrode holder integrated cooling device, a lower electrode rod mounted below the main body portion, and a power supply unit for applying predetermined power to the graphite electrode rod and the lower electrode rod.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be apparent to those skilled in the art that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know. Like numbers refer to like elements in the figures.

2 is a cross-sectional view of the graphite electrode holder integrated cooling device according to the present invention.

3 is a cross-sectional view of the graphite rod assembled in the graphite electrode holder integrated cooling device according to the present invention.                     

4 is a plan view of the graphite electrode holder integrated cooling device according to the present invention.

2 to 4, the graphite electrode holder integrated cooling device according to the present invention includes a holding member 110 for holding the graphite electrode rod 200, a central flow path 120 formed in the holding member 110, and The flow rate control unit 130 includes a plurality of injection nozzles 135 for adjusting the flow rate of the cooling water, and a plurality of cooling water vertical flow paths 140 formed in the holding member 110.

The apparatus further includes a power supply pipe 150 for supplying predetermined electric power to the graphite electrode rod 200, and a central cooling water pipe 160 for supplying predetermined cooling water to the central channel 120. In addition, the apparatus further includes an upper cooling water pipe 170 for supplying a predetermined cooling water to the flow rate adjusting unit 130. The upper coolant pipe 170 includes a predetermined pipe, an insulator 172 of a pipe fixing part for preventing damage caused by a magnetic field, and an insulating hose 174 for securing flexibility of pipe connection and easy disassembling and assembling lines. It includes more.

The holding member 110 is preferably formed in a predetermined cylinder with an empty inside. Of course, a variety of non-cylindrical shapes are possible. At this time, the shape of the inside is effective to be the same size as the graphite electrode (200). This may support the graphite electrode 200 from the shaking and vibration of the graphite electrode 200. It is preferable that the flow rate control unit 130 is also formed in the same shape as the holding member 110. In addition, the flow rate controller 130 is mounted on the holding member 110 and preferably has a predetermined slope. As a result, a predetermined space is formed between the flow rate control unit 130 and the graphite electrode 200, and a coolant may be located in the space, and the coolant located in this region may be the graphite electrode 200 through the vertical flow passage 140. ) Flows in through) to cool the graphite electrode rod 200. It is preferable that the flow rate adjusting unit 130 is provided with two euros and two euros jacket so that the cooling water can be uniformly sprayed. At this time, the vertical flow path 140 is configured to fit the nozzle 135 in the contact portion of the holding member 110 and the graphite electrode 200 so that the cooling water sprayed from the nozzle can flow smoothly through the graphite electrode 200. . The flow rate control unit 130 is preferably made of copper, and can be configured in a holder-integrated type and in an assembled and disassembled type that can be mounted.

Through this, when melting the scrap iron using the graphite electrode rod 200, it is possible to protect the cooling device from the generated by-products.

Hereinafter, an electric furnace including the above-mentioned graphite electrode holder integrated cooling device will be described.

5 is a view for explaining an electric furnace including a graphite electrode holder integrated cooling device according to the present invention.

Referring to FIG. 5, an electric furnace includes a body part 500 having a predetermined internal space, a graphite electrode rod 200 mounted to penetrate from an upper part of the body part 500 to an internal space of the body part 500, and a body part ( 500 is a graphite electrode holder integrated cooling device 100 for holding and cooling the graphite electrode rod 200 on the upper portion, the lower electrode rod 300 mounted to the lower portion of the body portion 500, and a predetermined inside of the body portion 500. It includes a lance 400 for blowing the material. In addition, the graphite electrode 200 and the lower electrode 300 may further include a predetermined power supply unit (not shown) for applying a predetermined power. The main body 500 may be formed as a lower passage having a space below and a cover covering the lower portion. In addition, the lower electrode 300 may be composed of a plurality. In addition, a separate discharge part for discharging molten steel may be formed in the main body part 500.

At this time, the scrap metal 600 is provided in the inner space of the main body 500. A negative voltage is applied to the graphite electrode 200 and a positive voltage is applied to the lower electrode 300 to melt the scrap iron 600 to produce molten steel. Here, oxygen can be blown. At this time, it is possible to prevent damage to the cooling device 100 due to the radiant heat generated from the furnace body and the melting of the scrap metal and scattering of molten steel generated when oxygen is blown.

The cooling device can be effectively protected from the radiant heat generated during operation of the mini-mill DC electric furnace of the present embodiment described above, and fly products (high-temperature solid, liquid) generated during flame, scrap metal melting and oxygen blowing. In addition, it is possible to completely solve the problem of the conventional melt loss deformation. In addition, by installing the cooling device on the upper part of the cooling water flowing through the graphite electrode rod due to the vibration generated during operation, and installing the vertical flow path 140 inside the holder to allow the cooling water to flow in the correct way even by vibration. Effective cooling can be achieved and breakage of the graphite electrode can be prevented.

As described above, the present invention can effectively cool the graphite electrode rods by allowing the cooling water to flow through the graphite electrode rods regardless of disturbing operations such as vibration generated during operation, thereby preventing graphite electrode wear and breakage.                     

In addition, since it can be used semi-permanently by installing the cooling device once, it is possible to solve the problem of downtime for replacing the cooling device.

In addition, material costs, replacement and repair costs can be reduced, and cost savings can be achieved through electrode breakage and wear protection.

Claims (5)

A holding member for holding the graphite electrode; A flow rate controller formed with a plurality of injection nozzles for controlling the flow rate of the coolant; A plurality of vertical flow paths formed in the holding member in a region where the holding member and the graphite electrode are in contact with each other; A central flow path formed in the holding member; And And a graphite electrode holder integrated cooling device including a central cooling water pipe for supplying predetermined cooling water to the central channel. The method according to claim 1, A power supply pipe for supplying predetermined power to the graphite electrode; And And an upper cooling water pipe for supplying predetermined cooling water to the flow rate adjusting unit. The method of claim 2, wherein the upper cooling water pipe, Predetermined piping; An insulator of a pipe fixing part for preventing damage caused by a magnetic field; And Cooling device with integrated graphite electrode holder including insulation hose for flexibility of pipe connection and easy disassembly of line. The method according to any one of claims 1 to 3, The flow rate adjusting unit is formed integrally with the holding member in the upper region of the holding member, or is mounted through a separate manufacturing, graphite electrode holder integrated cooling device formed to have a predetermined slope. A main body having a predetermined internal space; A graphite electrode rod penetrating from an upper portion of the main body to a predetermined space inside the main body; Claim 1 to 3 of the graphite electrode holder integrated cooling device for holding and cooling the graphite electrode rod on the main body portion; A lower electrode rod mounted below the main body portion; And An electric furnace comprising a power supply for applying a predetermined power to the graphite electrode and the lower electrode.

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