KR101159975B1 - guide hole for supplying sand of electric furnace - Google Patents

Abstract

The present invention relates to a sand input guide to an electric furnace. Specifically, a guide (H) for guiding sand is formed in a horizontal portion of the body furnace wall formed above the outlet of the electric furnace, and the molten steel slag does not leak out through the guide so as to prevent the formation of the current. The sphere is provided with a guide tube 42 protruding downward from the inner wall surface of the horizontal portion. According to this configuration, since the molten steel slag is blocked by the guide tube of the guide port so that the current is not formed in the guide port, sand can be easily introduced into the exit port, and sand injection time is reduced by reducing the guide cleaning time due to sand clogging. It is effective to reduce the cost.

Description

Guide hole for supplying sand of electric furnace

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sand input guide for an electric furnace, and more particularly, to a sand input guide for an electric furnace for easily inserting sand into a tap of an electric furnace.

In general, an electric furnace is a furnace for heating and dissolving a metal or an alloy using electricity. In the furnace body in contact with the molten metal, fixed and amorphous refractory are built in order to protect the furnace body from high temperature molten metal. Charged to dissolve the scrap iron in the electric furnace by applying a high voltage to the electrode to generate a high heat arc heat.

Electric furnaces are widely used in metal refining and are divided into resistance furnace, arc furnace and induction furnace according to the heating method. Among them, arc furnaces are used for steelmaking. The 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-phase electrode, and the power is three-phase alternating current and the capacity is hundreds to thousands of kilowatts. There is a large thing to reach, too.

The molten steel produced by melting the scrap metal in the electric furnace is taken to the ladle through the tap and then transferred to the post-processing when melting is completed. At this time, the tapping part during tapping operation in the electric furnace prevents the outflow of molten steel by putting sand before the operation, and when the tapping is completed, the tap opening is removed to remove tapping sand.

An object of the present invention is to provide a sand input guide of the electric furnace to facilitate the sand input operation to the tap of the electric furnace.

The sand injection guide of the electric furnace according to the present invention is formed with a guide for guiding the sand in the horizontal part of the body furnace wall formed above the outlet of the electric furnace, so that molten steel slag does not flow out through the guide so as to form now. To prevent the guide is characterized in that the guide tube protruding downward from the inner wall surface of the horizontal portion.

The upper end portion of the guide tube is formed to protrude upward from the outer wall surface of the horizontal portion so as to prevent clogging phenomenon of the guide hole due to foreign matter and foreign substances formed on the outer wall surface of the horizontal portion.

The cover is installed on the upper end of the guide tube to block the guide when not inserting the sand.

According to the sand injection guide of the electric furnace according to the present invention, since the molten steel slag is blocked by the guide tube of the guide and does not form now in the guide, sand can be easily introduced into the tapping hole, and the guide due to the sand clogging phenomenon It is effective in reducing sand input time by reducing the old washing time.

1 is a view schematically showing an electric furnace to which the sand input guide of the present invention is applied;
Figure 2 is a detailed view showing a sand injection guide according to an embodiment of the present invention,
3 is a view showing the guide Hc of the comparative example shown in comparison with the guide H of the present invention.

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

1 is a view schematically showing an electric furnace to which the sand input guide of the present invention is applied, and FIG. 2 is a detailed view showing the sand input guide formed in FIG.

As shown in the drawing, a plurality of upper electrodes 13 are installed at the center of the loop 12 covering the upper portion of the body 11 to re-dissolve scraps such as scrap steel to manufacture molten steel. The bottom electrode 14 is provided at the bottom to generate arc by energizing the upper electrode 13. On one side of the body of the electric furnace 10, the lance apparatus 30 for supplying the oxygen and carbon (carburizing material) necessary for refining, and the exclusion for excluding the slag (3) generated in the refining process to the slag port 22 Each sphere 15 is provided. In addition, the other side of the electric furnace 10 is provided with an EBT (Eccentric Bottom Tapping) tap 16 used to tap the molten steel 1 to the ladle 20 after the refining process is completed. The opener 17 is installed below the tap hole 16 to prevent the leakage of molten steel and sand during operation.

In the body 11 of the electric furnace 10, the furnace wall horizontal portion 11a is formed on the upper side of the tap hole 16, and the molten steel does not contact the inner wall of the tap hole 16 at the furnace wall horizontal portion 11a. Guide H is formed to guide the sand in before the operation so as to prevent leakage of molten steel.

The guide hole H protrudes downward from the inner wall surface of the horizontal portion 11a (protrusion length h1) while protruding upward from the outer wall surface of the horizontal portion 11a (protrusion length h2). ) Is provided.

Therefore, the molten steel slag S is prevented from flowing out through the guide hole H by the protruding length h1 protruding downward to prevent the present formation. Then, the blocking length of the guide hole H due to the now and foreign matter (D) formed on the outer wall surface of the horizontal portion (11a) by the protruding length (h2) protruding upwards.

The cover 44 is installed on the upper end of the guide tube 42 to block the guide port H when the sand is not injected. The cover 44 is rotatably installed in the horizontal direction by the hinge pin (45).

An injection pipe 46 for injecting sand is provided above the guide pipe 42 provided in the horizontal portion 11a, and the injection pipe 46 communicates with the sand container 48.

The lance of the lance device 30 is transferred into the electric furnace by a transfer means to supply oxygen and carbon (carburizing material) to the interior of the electric furnace during operation, the oxygen lance for supplying oxygen to the interior of the electric furnace, It is provided with the carbon lance which supplies carbon (carburizing material) inside.

In the operation of the electric furnace, the scrap is first charged into the furnace at about 75% of the total amount of the first charge, and then the remaining about 25% of the scrap is charged again, followed by the second melting process, and then the total amount of scrap is dissolved. When it is finished, go through the refining process. In such a dissolution and refining process, while setting an appropriate power pattern for each step in order to shorten the operating time and energizing, supplying oxygen and carbon (carburizing material) on the molten steel surface promotes dissolution.

By supplying carbon (carbonized material) and oxygen into the electric furnace, the dissolution time can be shortened by exothermic reaction by the reaction of carbon and oxygen. Oxygen supply is essential when melting the iron, but it causes various problems due to oxidation because oxygen lowers the ratio used to oxidize carbon components and encounters obstacles such as iron that is charged into the furnace, and oxidizes the iron. By oxidizing to promote electrode consumption, the slag forming property of the carbon by the carbon (carbonaceous material) supplied through the carbon lance is improved to reduce the consumption of the electrode 13.

Slag foaming is a phenomenon in which oxygen and carbon react at the interface between the upper surface of molten steel and the slag to generate gas such as carbon monoxide, which causes the slag to swell and surround the arc. Therefore, slag forming improves the arc heat transfer efficiency to the molten steel by preventing the exposure of the arc generated from the electrode, and contributes to the improvement of quality by preventing the nitrogen intake into the molten steel by the atmosphere and the cooling equipment from the high temperature arc. It serves to prevent leakage by protecting, and in particular, reduces electrode consumption by oxidation of the electrode.

When molten iron is used in the electric furnace operation, the molten iron in the molten iron decreases in proportion to the molten iron charge due to the heat of the molten iron itself and the oxidative heat of the oxidizing element during the oxygen extraction. Therefore, it is essential for the oxygen blowing pattern to hit the end point temperature and the end point carbon to secure the blowing pattern corresponding to the reduction of the electric power unit, that is, the processing time. These end point temperatures and end point carbons vary depending on the type of steel produced. Depending on the end point carbon concentration, the end point oxygen concentration is also inversely proportional to the carbon concentration. In other words, the higher the carbon concentration, the lower the end point oxygen concentration, so it is necessary to reduce the oxygen consumption in the high carbon concentration. For example, when the carbon concentration is 0.03%, the target oxygen concentration should be 900ppm, and at 0,08%, 400ppm, so the amount of blown oxygen will vary depending on the steel grade even at the same molten iron. After all, the end point carbon hit can be considered the same as the end point oxygen concentration hit.

In order to set the oxygen scavenging pattern in the electric furnace, the maximum allowable oxygen gas flow rate must be set first in the dissolution refining behavior step. The oxygen flow rate is somewhat different depending on the molten iron, but the maximum oxygen flow rate must be maintained to satisfy both the decarburization rate and the elevated temperature of the molten steel.

When the operation is completed, the opener 17 is opened to remove the sand blocking the tap hole 16, and the molten steel flows out through the tap hole 16 to tap into the ladle 20.

When the tapping is completed, open the cover 44 installed in the guide pipe 42 for the next operation, outgoing sand through the injection pipe 46 in the sand bucket 48 to receive the guidance of the guide pipe 42 Allow sand to fill the sphere 16.

3 is a view showing the guide Hc of the comparative example shown in comparison with the guide H of the present invention. As shown, in the guide Hc of the comparative example, the slag of the molten steel flows out through the guide Hc during operation to form now and is attached, thereby causing sand clogging and cap (cover) sticking phenomenon to clean the guide. There is a disadvantage in that the washing time is excessive and the time for putting sand is delayed, thus delaying the operation.

However, in the embodiment of the present invention, as shown in FIG. 2, the molten steel slag S does not flow out through the guide hole H by the protruding length h1 protruding downward of the guide pipe 42. Since the present invention is prevented from being formed, and the guide hole H formed on the outer wall surface of the horizontal portion 11a by the protruding length h2 protrudes upward prevents clogging of the guide hole H due to the foreign matter D, Sand injection can be facilitated.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. The scope of the technical protection shall be determined by the technical idea of the appended claims.

10: electric furnace 11: electric furnace body
11a: horizontal portion 16: exit hole
17: opener 42: guide
44: cover 45: hinge pin
46: input tube 48: sand bucket
D: Foreign object H: Guide
h1, h2: protruding length S: molten steel slag

Claims (3)

delete Guides for guiding sand are formed in the horizontal part of the body furnace wall formed above the exit of the electric furnace,
The guide is provided with a guide tube protruding downward from the inner wall surface of the horizontal portion so that the molten steel slag does not flow out through the guide to prevent the present formation,
Sand injection guide to the electric furnace characterized in that the upper end of the guide tube formed to protrude upward from the outer wall surface of the horizontal portion to prevent clogging of the guide due to the now and foreign matter formed on the outer wall surface of the horizontal portion. The method according to claim 2,
Sand injection guide of the electric furnace, characterized in that the cover is installed on the upper end of the guide pipe to block the guide when not injecting the sand.

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