KR20110004456U - device for cooling of electrode in electric furnace - Google Patents

Abstract

The present invention relates to an electrode furnace cooling apparatus of an electric furnace for supplying cooling water to a lower portion of a plurality of furnaces to prevent electrode rods from being exposed to the air to prevent oxidative wear of surface portions.

The configuration is a plurality of circular holes are formed in the inner peripheral surface to inject the coolant toward the outer circumference of each of the lower electrodes, a plurality of circular pipes spaced apart from each other so as to correspond to the gap between the electrodes, and in communication with each other to enable the supply of the coolant The connection pipe is connected to the outer circumferential surface of the circular tubes and supports the circular tubes, and the cooling water supply pipe is connected in communication with the connecting tube side and supplies the cooling water to the circular tubes.

According to the present invention, since the present invention can be placed in a narrow space around an electric furnace, space utilization is increased, and the overall cooling performance of the electrode is improved, thereby extending the life of the electrode, thereby reducing the cost incurred when replacing the electrode. Not only can it have a beneficial effect of improving the productivity of the operation.

Description

Device for cooling of electrode in electric furnace

The present invention relates to an electrode cooler of an electric furnace, and in particular, to cool the lower parts of the electrode, which is an arc generating medium, to reduce the surface wear phenomenon caused by the oxidation of the electrode.

In general, an electric furnace refers to a furnace for heating and dissolving a metal or an alloy by using electricity. Three electrodes are vertically installed at the top of the furnace to dissolve fuel charged in the furnace. As the arc heat of high heat is generated, the scrap metal in an electric furnace is melted.

This electrode is supported by lifting and lowering using a master arm and a master cylinder.

The master cylinder is composed of a columnar cylinder housing integrally connected with the master arm, and a cylinder rod disposed inside the cylinder housing to lift the cylinder housing.

The electric furnace is constructed so that the end is located inside the furnace through the furnace cover and the furnace cover to cover the upper part of the furnace when melting the scrap, and to block the outside of the furnace when melting the scrap. It consists of an electrode that generates high heat through the arc (arc) discharge between the scrap iron.

In addition, the inner side of the furnace is laminated with refractory bricks to form a heat insulating layer, and the outer side is formed of a thick steel sheet to form an outer shape.

In addition, both the furnace and the furnace lid are provided with a cooling water pipe inside, so that the cooling water is supplied / circulated from the collection tank by the cooling water pump, and the cooling water discharged after the heat exchange is cooled by the cooling tower and collected again in the collection tank.

On the other hand, when the electrode is in contact with the atmosphere in the heated state by the arc heat occurs oxidative consumption of the surface, this consumption phenomenon is increased as the temperature of the electrode is increased, there is a need for a device for cooling the electrode.

The cooling device of the electrode rod installs an electrode spray covering the upper part of the electrode rod, connects the cooling water pipe between the electrode spray and the sump, and installs a cooling water pump and a flow control valve for supplying the cooling water to the cooling water pipe. Is supplied to the electrode spray to inject cooling water onto the upper outer circumferential surface of the electrode to achieve cooling.

The electrode spray is disposed on the upper side of the furnace cover, and consists of a circular tube surrounding the outer circumference of each electrode rod, and a straight tube connected to one side of the circular tube and connected to the cooling water supply pipe through a connector.

The lower surface of the circular tube is provided with injection holes at regular intervals over the entire circumferential direction.

Therefore, when the circular tube is installed to surround the electrode outer circumference and then supply the cooling water, the cooling water is injected to the surface of the electrode through the injection hole to cool the electrode.

Since the cooling device of the electrode is to cool the sprayed water to the upper side of the electrode rod located on the upper side relative to the furnace cover, in fact, even though the lower portion of the electrode is a portion that generates more heat than the upper portion, There is a disadvantage that the cooling effect is not transmitted until.

In addition, when the furnace cover is swiveled due to the charging of scrap metal scrap, the lower part of the heated electrode is exposed to the air and oxidized to the air, thereby causing surface wear.

Therefore, due to the above reasons, the life of the electrode is shortened and must be replaced frequently. Therefore, there is a problem in that the electrode is expensive to replace and the operation is stopped.

In addition, since the electrode of the electric furnace is composed of three, there is a disadvantage that the configuration of the device for cooling each electrode is complicated and the space utilization of the place where it is installed is low.

The present invention is designed to solve the above problems, the purpose of which is to cool the lower part of the three electrodes at the same time to increase the space utilization, and also improve the electrode cooling performance, the life of the electrode This is to provide an electrode cooling apparatus of the electric furnace to increase, and to reduce the electrode replacement cost.

The present invention for achieving the above object is a plurality of circular pipes are disposed adjacent to the electric furnace and formed around the outer circumference of each of the lower electrode rods and a plurality of injection holes are formed on the inner peripheral surface and spaced apart from each other,

A connecting tube connected to and spaced from the circular tubes;

It is connected to the connection pipe side and characterized in that it comprises a cooling water supply pipe for supplying cooling water to the circular pipe.

An opening / closing valve for opening and closing a supply flow path of cooling water is disposed in the cooling water supply pipe.

The injection hole of the circular tube is formed such that the angle of formation of the injection hole is greater than 0 ° and less than 90 ° so as to spray the coolant above the inner circumferential surface.

The present invention is to supply a coolant to the lower portion of the electrode rods to prevent the electrodes are exposed to the atmosphere to easily oxidized wear, according to the present invention is placed in a narrow space around the furnace Since it is possible to increase the space utilization, and to improve the overall cooling performance of the electrode can extend the life of the electrode, it is possible to reduce the costs incurred when replacing the electrode, as well as to improve the productivity of the operation.

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

Electrode electrode cooling apparatus of the electric furnace according to the present invention, when described with reference to Figures 1 to 3, the configuration is a plurality of injection holes 115 in the inner circumferential surface to inject the cooling water toward the outer circumference of the lower end of the electrode 10 A plurality of circular tubes 110 formed to be spaced apart from each other so as to correspond to the gaps between the electrode rods 10, and the circular tubes 110 connected to the outer circumferential surfaces of the circular tubes 110 so as to communicate with each other so as to supply the cooling water. The connection pipe 120 for supporting them, and the connection pipe 120 is connected in communication with the coolant supply pipe 130 for supplying coolant to the circular pipe (110).

The circular tubes 110 are disposed adjacent to the outside of the electric furnace (not shown).

The connection pipe 120 is connected to communicate with the outer circumferential surface of the circular pipe 110, and has an end structure is connected to each other by welding or the like.

The cooling water supply pipe 130 may be directly connected to the connection pipes 120 and the circular pipe 110, or may be connected to supply the cooling water into the circular pipe 110 through the connection pipe 120.

In addition, the cooling water supply pipe 130 is not shown in the figure, but is connected to the cooling water pump for pumping the cooling water.

Cooling water supply pipe 130 has an opening and closing valve 150 for performing the supply or blocking operation of the cooling water is disposed at the end.

The circular tube 110 is configured in a ring shape, and has a structure in which a gap between each other is supported through the connection pipe 120 so that the ring portion is arranged on the same line as the lower portions of the electrode rods 10.

The injection holes 115 of the circular tube 110 are formed at an angle within the range of more than 0 ° and less than 90 ° inward to spray the coolant toward the lower surface of the electrode rods 10 positioned on the upper side.

That is, the injection holes 115 of the circular pipe 110 vary the injection angle of the suitable coolant according to the distance and the position of the lower portion of the electrode rods 10, but does not deviate from the above-described angle range.

Reference numeral “50” denotes an electrode spray 50 disposed below the master arm to cool the electrode 10 by spraying cooling water on the upper portions of the electrode 10.

Referring to the operation of the present invention having such a configuration as follows.

When the scrap metal is charged after the furnace lid (not shown) of the electric furnace is opened in a pivoting operation, the electrode rods 10 are exposed to the atmosphere.

Since the operation of elevating the electrode 10 is the same as that of the existing master arm and the master cylinder will not be described in detail here.

When the lower part of each electrode 10 is moved to the upper side of the circular tube 110 corresponding to each other or located inside the ring of the circular tube 110, opening and closing valve 150 to open the cooling water inside the circular tube 110 To supply.

At this time, the cooling water is supplied to the connection pipe 120 and the circular pipe 110 through the cooling water supply pipe 130, and then supplied to the injection holes 115 of the circular pipe 110, respectively.

Since the forming angle of the injection hole 115 is formed to be upward, the cooling water is injected upward while passing through the injection hole 115 and is injected to the lower surface side of each electrode rod 10.

The injected cooling water vaporizes as it is evaporated as it comes into contact with the lower surface of each electrode 10 heated to a high temperature.

This water vapor forms a water vapor barrier that blocks the lower portions of the electrodes 10 from being directly in contact with the atmosphere.

As a result, the coolant cools the lower portion of the electrode 10, and serves to block the atmosphere and the lower portion of the electrode 10, thereby preventing surface wear of the electrode 10.

In this case, the electrode cooler of the electric furnace according to the present invention, the lower portion of the three electric furnace electrode 10 can be cooled simultaneously with the cooling water, respectively, because of the cooling water rather than cooling the electrode 10 individually Concentrating the injection range and cooling simultaneously can have more efficient cooling performance.

When the coolant is not injected into the electrode rod 10, the closing valve 150 is closed to stop the supply of the cooling water to the cooling water supply pipe 130.

This prevents unnecessary cooling water from being supplied when the electrode rod 10 is not positioned at the upper portion of the circular tube 110 or the ring portion of the circular tube 110.

Due to the characteristic features of the present invention as described above, the cooling performance of the electrode 10 is improved, so that the consumption of the electrode 10 is reduced, and the life of the electrode is greatly increased. It is effective.

1 is a perspective view showing an electrode cooling device of an electric furnace according to the present invention.

Figure 2 is a front view showing an installation state of the present invention.

Figure 3 is a perspective view showing a state of use of the subject innovation.

Explanation of symbols on the main parts of the drawings

10: electrode 110: round tube

115: injection hole 120: connector

130: cooling water supply pipe 150: on-off valve

Claims (3)

A plurality of circular tubes 110 disposed adjacent to the electric furnace and surrounding the outer circumference of each lower portion of the electrode rods 10, and a plurality of injection holes 115 are formed on the inner circumferential surface and spaced apart from each other; A connecting pipe 120 communicatively connected to the circular pipes 110 and maintaining a spacing therebetween; Connected to the connection pipe 120 side and the electrode rod cooling apparatus of the electric furnace characterized in that it comprises a cooling water supply pipe 130 for supplying cooling water to the circular pipe (110). The method according to claim 1, The electrode rod cooling apparatus of the electric furnace, characterized in that the opening and closing valve 150 for opening and closing the supply flow path of the cooling water in the cooling water supply pipe 130. The method according to claim 1 or 2, The injection hole 115 of the circular tube 110, the electrode rod cooling apparatus of the electric furnace, characterized in that the formation angle of the injection hole 115 is formed in more than 0 ° and less than 90 ° to inject the coolant to the upper inner peripheral surface.

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