KR20110132276A - Closed type electrode apparatus of arc furnace - Google Patents

Abstract

PURPOSE: A closed electrode unit of an electrical furnace is provided to prevent the emission of gas including carbon monoxide or carbon dioxide from an electrical furnace since the open space between the electrode bar and electrode lifting unit of the electrical furnace is closed. CONSTITUTION: A closed electrode unit of an electrical furnace comprises an electrode bar(102), a cover(104), a water cooling tank(180), an electrode lifting unit(110), an electrode reducing unit(120), and a closing unit. The cover protects a part of the electrode bar. The water cooling tank protects the lower end of the cover. The electrode lifting unit lifts the cover and the electrode bar. The electrode reducing unit is installed on the electrode lifting unit and presses the electrode bar. The closing unit closes the gap between the cover and the electrode bar. The closing unit closes the gap between the water cooling tank and the cover.

Description

Electric furnace hermetic electrode unit {CLOSED TYPE ELECTRODE APPARATUS OF ARC FURNACE}

The present invention relates to an electric furnace, and more particularly to an enclosed electrode unit of an electric furnace.

Electric furnaces are widely used in metal refining as furnaces that use electric heat to heat. According to the heating method, it is divided into resistance furnace, arc and induction furnace. The arc furnace of the electric furnace is a furnace widely used for steel making and ferroalloy production. Arc furnaces are heated by flowing an electric current in the form of an arc between the molten material placed in the furnace and the three electrodes. There are also large-sized power supplies with three-phase alternating current and capacities of several hundred to tens of thousands of kW. Since the arc current varies depending on the melted material, it is necessary to control the position of the electrode at all times to maintain the arc current at a constant value as possible.

In addition, the arc furnace is inserted into the furnace body through the through hole formed in the cover of the furnace body, the dust is not only released through the gap between the electrode and the through hole, the carbon monoxide or carbon dioxide gas is released to the outside.

An object of the present invention is to seal the open space existing between the electrode of the electric furnace and the elevating device to prevent the release of gas such as carbon monoxide or carbon dioxide generated in the electric furnace.

The problem to be solved by the present invention is not limited thereto, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

Electrically sealed electrode unit of the present invention for achieving the above object is an electrode rod; A mantle surrounding a part of the electrode; A water cooling outer cylinder installed to surround the mantle at the bottom of the mantle; An electrode elevating device for elevating the mantle and the electrode; An electrode lowering device installed in the electrode elevating device and pressing the electrode bar; And an electrode side sealing part for sealing a gap between the mantle and the electrode and sealing a gap between the water cooling outer cylinder and the mantle.

According to an embodiment of the present invention, the electrode side sealing portion is an O-ring insulating seal installed between the water-cooled outer cylinder and the mantle; An o-ring top seal installed at a gap between the mantle and the electrode at an upper end of the mantle; And a seal cover covering the top seal.

According to one embodiment of the invention, the electrode elevating device is a cylinder unit which is installed in a vertical direction to the fixed frame of the electric furnace; And a lifting bracket connected to the rod end of the cylinder unit and fixed to the mantle.

According to an embodiment of the present invention, the electrode lowering device is installed on the lifting bracket.

According to an embodiment of the present invention, the electrode lowering device is installed on the lifting bracket, the lower clamping unit for clamping / unclamping the electrode; And an upper clamping unit installed on the lifting bracket and configured to clamp / unclamp the electrode and to move the electrode downward by a predetermined distance while clamping the electrode.

The present invention has the effect of preventing the emission of gases such as carbon monoxide or carbon dioxide generated in the electric furnace.

In the present invention, the height of the electrode rod and the reduction of the electrode rod are possible.

In addition, the gas generated in the electric furnace is diluted with external air using a dust collector and discharged.However, a high concentration of carbon monoxide or carbon dioxide generated in a closed electric furnace to which the device is applied can be used for pre-reduction or preheating, thereby saving energy. It can work.

1 is a block diagram showing an electric furnace according to an embodiment of the present invention.
FIG. 2 is an enlarged view illustrating main parts of the electrode of FIG. 1.
FIG. 3 is an enlarged view illustrating main parts of the electrode of FIG. 1.

Hereinafter, embodiments of the present invention will be described in more detail with reference to FIGS. 1 to 3. The embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the following embodiments. This embodiment is provided to more completely explain the present invention to those skilled in the art. Therefore, the shape of the elements in the drawings are exaggerated to emphasize a more clear description.

1 is a block diagram showing an electric furnace according to an embodiment of the present invention. FIG. 2 is an enlarged view illustrating main parts of the electrode of FIG. 1. FIG. 3 is an enlarged view illustrating main parts of the electrode of FIG. 1.

Referring to FIG. 1, an electric furnace 1 for melting an iron-containing material such as ferroalloy includes a furnace shell (hereinafter referred to as a main body) 10, a cover 20, and an electrode unit of a three-phase alternating current method. 100 and a power feeding unit 90.

The main body 10 is provided with a cover 20 for closing the upper body. The raw material inlet tube 22 is installed at one side of the edge of the cover 20, and a dehumidification duct 24 for exhausting fugitives and gases generated inside the main body 10 is disposed at a position opposite to the raw material inlet tube 22. Is installed. The inside of the main body 10 is forced exhaust through the ventilation duct to generate a negative pressure therein. Three through holes 26 are provided near the center of the cover 20. The electrode rod 102 of the electrode unit 100 is disposed through the through hole 26. In the present embodiment, only two electrode units 100 and two through holes 26 are disclosed for convenience of drawing.

The power supply unit 90 is for supplying power to the electrode rod 102, the electrode holder 92 in contact with the lower end of the electrode rod 102, the tapered ring 94 for clamping the electrode holder 92, and tapered A hanger rod 96 holding the ring 94 and a conductive tube 98 for supplying power to the electrode holder 92 and a flexible cable 99 connected to the conductive tube 98. The power supply unit 90 supplies power to the electrode 102 through the flexible cable 99-the conducting tube 98-the electrode holder 92.

The electrode units 100 are all made of the same configuration. Therefore, in this embodiment, one electrode unit will be described.

1 to 3, the electrode unit 100 includes an electrode rod 102, a mantle 104, an electrode elevating device 110, an electrode lowering device 120, a water cooling outer cylinder 180, and a sealing means. .

The electrode rod 102 may be inserted into the main body 10 through the through hole 26 of the cover 20. The lower end of the electrode 102 is positioned to be immersed in the melt to a certain depth. When a high voltage is applied to the electrode rods 102 of the electrode units 100, high-temperature arc heat and resistance heat are generated to melt the raw material supplied into the main body 10.

The electrode 102 is shortened in length due to high heat and wear during operation. Therefore, when the length of the electrode 102 becomes short, if the carbon case is further connected to the electrode 102 and the carbon paste is supplied therein, the electrode paste extends while the carbon paste is melted and cured during the process. Is formed.

The mantle 104 is installed to surround the electrode rod 102. There is a gap between the mantle 104 and the electrode rod 102.

The electrode elevating device 110 is for adjusting the height of the electrode (102). Since the electrode rod 102 should be immersed in the melt at a predetermined depth, the electrode elevating device 110 adjusts the height of the electrode rod 102 according to the height of the melt in the body 10. The electrode elevating device 110 is connected to the cylinder unit 112 which is installed in the vertical direction on the fixed frame 2 of the site in which the electric furnace 1 is installed, and the end of the rod 114 of the cylinder unit 112 is connected to the mantle ( And a lifting bracket 116 secured to 104. A guide roller 190 for guiding the mantle 104 moved by the electrode elevating device 110 is installed between the fixed frame 2 and the mantle 104 on which the electrode elevating device 110 is installed.

The electrode lowering device 120 is installed at the lifting bracket 116. The electrode lowering device 120 has a role of reducing the electrode rod 102 by a length consumed during the steelmaking process, and a role of holding the electrode rod 102. As shown in the figure, the upper end of the electrode 102 exposed to the upper end of the mantle 104 is fixed by the electrode lowering device 120, the lower end of the electrode 102 exposed to the lower side of the mantle 104 of the power supply unit 90 The electrode holder 92 is fixed to the electrode holder 92 installed on the tapered ring 94. The electrode rod 102 is not fixed to the lower end of the electrode rod 102 but is held only at a constant pressure. By pressing down.

The electrode lowering device 120 includes a lower clamping unit 120b and an upper clamping 120a unit. The electrode lowering device 120 is located at the upper end of the electrode 102 exposed from the mantle 104. The upper clamping unit 102a performs an operation of clamping / unclamping the electrode rod 102 and a pressing operation of moving the electrode rod 102 down a predetermined interval while clamping the electrode rod 102. The lower clamping unit 120b performs a clamping / unclamping operation. Looking at the electrode pressing process of the electrode lowering device 120, the upper clamping unit (120a) is in the clamping state, the lower clamping unit (120b) through the pressing operation in which the upper clamping unit (120a) moves down in the unclamping state The electrode rod 102 is pressed down. When the pressing of the electrode 102 is completed, the lower clamping unit 120b is clamped and the upper clamping unit 120a is unclamped, and the upper clamping unit 120a returns to its original position.

The water-cooled outer cylinder 180 is positioned to surround the mantle at the bottom outside of the mantle 104 and is fixedly installed on the mantle 104. The water-cooled outer cylinder 180 is spaced apart from the mantle 104 by a predetermined interval. The water-cooled outer cylinder 180 is raised and lowered together with the mantle 104. The water-cooled outer cylinder 180 is guided by the guide rollers 30 installed on the cover during the ascent and descent.

The sealing means may be divided into a cover side sealing part 130 and an electrode side sealing part 140.

The cover side sealing part 130 includes an air curtain nozzle 132 provided in a ring shape along the through hole 26 on the upper surface of the cover 20. The air curtain nozzle 132 injects nitrogen gas whose pressure is controlled to block the outflow of gas and the outside air through the gap between the water cooling outer cylinder 180 and the through hole 26. In particular, the air curtain nozzle 132 includes a double seal 134 in the form of an O-ring in contact with the water-cooled outer cylinder 180. The double seal 132 is installed on the body of the air curtain nozzle 130. As such, the cover side sealing part 130 may block a gap between the through hole 26 and the water cooling outer cylinder 180.

The electrode-side sealing part 140 is an O-ring insulating seal 142 installed between the water-cooled outer cylinder 180 and the mantle 104, and a gap between the mantle 104 and the electrode rod 102 on the top of the mantle 104. O-ring-shaped top seal 144 is installed in the seal cover 146 covering the portion. The heat insulating seal 142 is a sealing material provided with a heat insulating material below the main body direction. The heat insulating seal 142 blocks gas and external air inflows to the outside through the gap between the water cooling outer cylinder 180 and the mantle 104. The top seal 144 and the seal cover 146 block the outflow of gas and outside air through the gap between the mantle 104 and the electrode 102.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

1: electric furnace 10: main body
20: cover 100: electrode unit
102 electrode 104 mantle
110: electrode elevating device 120: electrode lowering device
180: water-cooled outer cylinder

Claims (5)

In the electrically sealed electrode unit:
Electrode;
A mantle surrounding a part of the electrode;
A water cooling outer cylinder installed to surround the mantle at the bottom of the mantle;
An electrode elevating device for elevating the mantle and the electrode;
An electrode lowering device installed in the electrode elevating device and pressing the electrode bar; And
And an electrode side sealing part for sealing a gap between the mantle and the electrode and sealing a gap between the water cooling outer cylinder and the mantle. The method of claim 1,
The electrode side sealing part
O-ring insulating seal is installed between the water-cooled outer cylinder and the mantle;
An o-ring top seal installed at a gap between the mantle and the electrode at an upper end of the mantle; And
An electrically sealed electrode unit comprising a seal cover covering the top seal. The method according to claim 1 or 2,
The electrode elevating device
A cylinder unit installed in a direction perpendicular to the fixed frame of the electric furnace; And
The rod end of the cylinder unit is connected, the electrically sealed electrode unit comprising a lifting bracket fixed to the mantle. The method according to claim 1 or 2,
The electrode lowering device
The electric furnace sealed electrode unit, characterized in that installed in the lifting bracket. The method of claim 3, wherein
The electrode lowering device
A lower clamping unit installed on the lifting bracket and clamping / unclamping the electrode; And
And an upper clamping unit installed on the lifting bracket and clamping / unclamping the electrode rod and moving the electrode rod at a predetermined interval in the clamped state of the electrode rod to push down the electrode rod.

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