KR100923881B1 - Ladle for argon gas automatic injection apparatus - Google Patents

Abstract

The present invention relates to an argon gas injection device, in particular one side of the ladle (ladle) receiving the tough molten steel refined and dissolved in the furnace of the steel mill through argon through the elastic force when the ladle is seated or raised Argon gas injection device is provided to open and close the gas supply path so that argon gas is automatically injected during refining operation, so that argon gas can be supplied quickly and safely without a separate operator and absorbs the impact of load when ladle is seated. It relates to an argon gas auto-injection device for ladles. Its configuration is an argon gas injection device installed in a ladle which is a molten steel that receives molten steel, which has been refined and dissolved in a furnace of a steelmaking plant, and in the upper part, argon gas is injected into the ladle. A contact plate coupled to the injection pipe forming the path and being in close contact by a pressing operation to serve as a coupler; The nozzle is positioned downwardly on the same axis as the contact plate and moves upward and downward depending on contact with the contact plate to open and close an argon gas supply path, and a nozzle spring for providing an elastic force for flowing the nozzle. A housing formed with an internally coupled to the bottom center to form an inlet pipe for forming a path for transferring argon gas introduced from the outside; The outer diameter of the housing is formed with a housing spring to help the up and down flow of the housing in contact with the contact plate, both sides include a support plate for supporting the housing while moving up and down by the elastic force of the housing spring. It is done.

Steelmaking, Ladle, Gas Injection Device

Description

Lagon for argon gas automatic injection apparatus

The present invention relates to an argon gas automatic injection device for steelmaking ladle, in particular, one side of the ladle (ladle) receiving the molten steel that is refined and dissolved in the furnace of the steelmaking plant, the seating or raising of the ladle Argon gas automatic injection device that opens and closes the argon gas supply path through elastic force at the time, so that argon gas is automatically injected during refining operation. The present invention relates to an argon gas auto-injection device for a ladle that absorbs an impact by the ladle.

In general, molten steel, which is refined and melted in a furnace of a steelmaking plant, is subjected to ladle, which is sent to the next process. Cleanliness is low due to injuries of inclusions.

For this reason, high purity molten steel can be obtained by passing an inert gas (argon gas) into the molten metal through a porous plug installed under the ladle.

In other words, the molten steel received on the ladle is subjected to secondary refining to adjust the composition and temperature. The secondary refining is performed by supplying argon gas, which is an inert gas, through a porous plug of porous refractory to the molten metal in the ladle. To reflux, which is essential for fine component and temperature adjustment.

This secondary refining operation is performed by mounting the ladle on the ladle stand (not shown) formed in the vacuum tank, and connecting the gas pipe installed in the ladle stand and the ladle for the supply of argon gas.

Such a conventional gas supply device has a female coupler (12) formed at one end of the injection pipe (11) formed in the lower portion of the ladle (10), as shown in Figure 1a and 1b, to supply argon gas from the outside The male coupler 14 formed at one end of the argon inlet pipe 13 formed for this purpose is configured to allow the operator to directly supply the argon gas to each other.

However, the conventional gas supply device 100 as described above is waiting for a separate worker other than the worker seating the ladle 10 in the refining facility for argon gas supply when the ladle 10 is seated. The female coupler 12 and the male coupler 14 have to be interconnected manually, and when the refining operation is completed, the worker has to separate the female coupler 12 and the male coupler 14 directly. .

In addition, the female coupler 12 and the male coupler 14 have a problem in that argon gas is leaked due to abrasion of the contact portion due to frequent coupling and disconnection operations when argon gas is supplied.

Accordingly, the present invention has been made to solve the above problems, an object of the present invention is to open the gas supply path by the weight of the ladle when the ladle is settled to automatically supply argon gas and at the same time the gas supply path at the time of rising of the ladle By closing the supply of argon gas to stop, it is to provide an automatic argon gas injection device for steelmaking ladle to achieve a smooth and easy supply and interruption of the gas safely and conveniently without a separate operator.

The present invention for achieving the above object is an argon gas injection device which is installed in the ladle which is a molten iron gourd receiving a molten steel that is refined and dissolved in the furnace of the steelmaking plant, the argon at the top A contact plate coupled to an injection pipe forming a path for transferring gas into the ladle and being in close contact by a pressing operation to serve as a coupler; The nozzle is positioned downwardly on the same axis as the contact plate and moves upward and downward depending on contact with the contact plate to open and close an argon gas supply path, and a nozzle spring for providing an elastic force for flowing the nozzle. A housing formed with an internally coupled to the bottom center to form an inlet pipe for forming a path for transferring argon gas introduced from the outside; The outer diameter of the housing is formed with a housing spring to help the up and down flow of the housing in contact with the contact plate, both sides are made of a support plate for supporting the housing while moving up and down by the elastic force of the housing spring It is characterized by.

Optionally, the nozzle is characterized by consisting of a top plate formed with a plurality of argon gas supply path and a bottom plate which is integrally coupled to each other by a strut at intervals with the top plate.

In addition, an O-ring for airtightness is formed on the upper surface of the housing and the lower plate upper surface of the nozzle.

In addition, the nozzle spring is formed of a compression spring, the housing spring is formed of a leaf spring, it is characterized in that to prevent damage by absorbing the shock during the mounting of the ladle.

As described above, the present invention enables argon gas to be automatically supplied and blocked when the ladle is seated and raised, and the argon gas is easily provided by the wide contact plate and the housing even when the ladle's seating position is slightly shifted. Supply is possible.

In addition, when the ladle is seated, the shock can be absorbed twice by the nozzle spring and the housing spring to prevent damage due to the impact, and there is no need for a separate worker for connecting the female and male couplers, thereby reducing labor cost and labor. There is an effect such as to improve the safety of the work.

Hereinafter, a preferred embodiment of the argon gas automatic injection device for steelmaking ladle according to the present invention will be described in more detail with reference to the accompanying drawings.

Here, the components having the same function in all the drawings below are repeated descriptions using the same reference numerals, and the following terms are defined in consideration of functions in the present invention, which is a unique commonly used It should be interpreted as meaning.

2 is a view showing a separated state of the automatic gas injection device according to a preferred embodiment of the present invention, Figure 3 is a view showing a combined state of Figure 2, Figure 4 is an automatic gas injection according to a preferred embodiment of the present invention It is a figure which shows the use condition which installed the apparatus. 5A, 5B, 5C, and 5D are diagrams illustrating an operating state of the gas automatic injection device according to the preferred embodiment of the present invention.

As shown in FIGS. 2 to 5, the gas auto-injection apparatus 200 of the present invention is roughly composed of a contact plate 210, a housing 220, a nozzle 230, and a support plate 240.

The contact plate 210 is formed so as to overlap by using a metal material and a cushioned material to facilitate sufficient strength and perfect adhesion and shock absorption, the center portion is a steel that is refined and dissolved in the furnace of the steel mill An injection pipe 211, which is one of the argon gas supply paths supplied to the inside of the ladle 10 that is a molten metal receiving molten metal, is formed.

In addition, the contact plate 210 is fixedly coupled to one side of the ladle 10 to form the same axis as the housing 220, the housing 220 by the raising or lowering operation of the ladle 10 It acts as a coupler to open or close the argon gas supply channel while being in close contact with or separated from the gas.

The housing 220 is formed of a cylindrical shape using a metal, the upper flange and the body is formed with a different diameter (P), the outer diameter portion of the flange (P) for straight guidance in the up and down flow A guide bar 221 is formed, a hollow portion 222 having a different diameter and forming a plurality of steps for accommodating the nozzle 230 is formed at a central portion thereof, and a bottom 225 is formed at a lower side thereof.

A groove 223 is formed on an upper surface of the housing 220, and an o-ring 224 is provided in the groove 223 to maintain an airtight state to prevent the leakage of argon gas when the contact plate 210 is in close contact with the contact plate 210. Insert is formed.

In addition, since the guide bar 221 is formed with a screw 221a for coupling on the lower side, it is fitted to the support plate 240, and then coupled by a nut 221b to support the support plate during the vertical flow of the housing 220. 240 is supported.

The bottom 225 of the housing 220 is formed integrally or formed by any one of which is detachably formed by the fastener 225a, and the center portion of the supply path for argon gas introduced from the outside. One drawing pipe 226 is formed.

In addition, a groove 227 is formed on an upper surface of the bottom 225, and an o-ring 228 is formed in the groove 227 to maintain an airtight state to prevent the flow of argon gas.

Here, the pipe material is a pipe steel pipe, carbon steel pipe, stainless steel pipe and copper pipe, etc. are used, but as the material of the injection pipe 211 and the inlet pipe 226 depending on the operating pressure, the type and temperature of the fluid. It is preferable to use a gas pipe.

The nozzle 230 is a top plate 231 formed with a plurality of gas discharge holes 231a, which is one of the argon gas supply paths, and a coupling formed at the center to have a space on the same axis as the top plate 231. It consists of a support 232 having a screw 232a and a lower plate 233 integrally coupled to each other by a nut 232b.

The upper plate 231 has a plurality of grooves 231b formed on sidewalls, and the groove 231b is formed on the upper surface of the housing 220 while argon gas is ejected when the contact plate 210 comes in close contact with the lower plate. To clean up the dust

Grooves 233a are formed on the upper surface of the lower plate 233, and when the grooves 233a are not in close contact with the contact plate 210, the airtight state is maintained to prevent the outflow of argon gas. An o-ring 233b for insertion is inserted.

The support plate 240 has a housing accommodating hole 241 for accommodating and supporting the housing 220 in a substantially central portion, and accommodates the guide bar 221 on both sides of the housing accommodating hole 241. A guide bar receiving hole 242 for supporting is formed.

In addition, the support plate 240 is formed coaxially with the contact plate 210 on one side of the vacuum tank 20 for accommodating the ladle 10 to raise or lower the ladle 10. It serves to support the housing 220 which flows up and down by.

Argon gas automatic injection device 200 of the present invention configured as described above, the nozzle spring 234 for providing an elastic force to the hollow portion 222 formed inside the housing 220, and to the nozzle spring 234 The nozzle 230 which flows up and down is inserted by this.

The housing 220 is inserted into the housing receiving hole 241 formed in the support plate 240, and the guide bar 221 of the housing 220 is inserted into the guide bar receiving hole 242. .

At this time, between the support plate 240 and the flange (P) of the housing 220 is installed a housing spring 229 to help the vertical flow of the housing 220 in close contact with the contact plate 210, The nut 221b is fastened to the screw 221a of the guide bar 221 protruding to the bottom of the support plate 240.

Here, the nozzle spring 234 is formed of a compression spring, the housing spring 229 is preferably formed of a leaf spring, the nozzle spring 234 and the housing spring 229 is a ladle 10 When descending, the shock is absorbed to prevent damage and at the same time open the argon gas supply.

Referring to the working state of the present invention configured as described above are as follows.

First, the argon gas automatic supply device 200 according to the present invention is installed inside the housing 220 in a state in which the ladle 10 is not seated on a ladle stand (not shown) installed in the vacuum tank 20. The upper plate 231 of the nozzle 230 protrudes to the upper portion of the housing 220 by the elastic force of the nozzle spring 234, the lower plate 233 is in close contact with the bottom surface of the hollow portion 222 to maintain an airtight state Doing.

In this state, when the ladle 10 transferred to the crane is placed on the ladle stand installed in the vacuum tank 20, the contact plate 210 formed on one side of the ladle 10 is formed of the housing 220. While pressing from the nozzle 230 protruding upward, the housing 220 is pressed down.

At this time, the upper plate 231 of the nozzle 230 is a groove 231b formed on the side wall to remove dust falling on the upper surface of the housing 220 while argon gas is ejected when the contact plate 210 is in close contact with each other. Blow up and clean

As such, when the ladle 10 is completely seated on the ladle stand, the housing 220 and the nozzle 230 are pressed down by the contact plate 210 and lowered to closely contact the bottom surface of the hollow part 222. The lower plate 233 is spaced apart to open the argon gas supply path.

Accordingly, the inlet pipe 226 formed at the center of the bottom 225 of the housing 220 to transfer the argon gas introduced from the outside and formed at the center of the upper surface of the contact plate 210 to ladle the argon gas to the ladle. Injection pipes 211 which are transferred to the inside of 10 are interconnected to supply argon gas.

When the inlet pipe 226 and the inlet pipe 211 are interconnected as described above, argon gas is supplied to the ladle 10 to agitate the molten metal therein to induce temperature and component homogenization of the molten water and to separate the inclusions to raise the cleanliness. Will increase.

On the other hand, after the refining operation is completed, the ladle 10 is lifted from the ladle stand.

At this time, the housing 220 and the nozzle 230 pressed by the contact plate 210 formed on one side of the ladle 10 are caused by the elastic return force of the nozzle spring 234 and the housing spring 229. As it is pushed up, the lower plate 233 of the nozzle 230 is in close contact with the bottom surface of the hollow part 222 of the housing 220, thereby maintaining airtightness to block the inflow of argon gas.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various changes, modifications, and equivalent changes to other embodiments may be made without departing from the technical spirit of the present invention. It will be apparent to those skilled in the art to which the invention pertains.

Figure 1a is a view showing a female coupler and a male coupler gas injection device for a conventional steelmaking ladle.

1B is a view illustrating a use state in which a female coupler and a male coupler are installed.

2 is a view showing a separated state of the automatic gas injection device according to an embodiment of the present invention.

3 is a view showing a combined state of FIG.

4 is a view showing a state in which the gas automatic injection device is installed according to a preferred embodiment of the present invention.

5A, 5B, 5C, and 5D are views illustrating an operation state of the gas auto-injection apparatus according to the preferred embodiment of the present invention.

※ Explanation of code about main part of drawing ※

200: gas injection device 210: contact plate

211 inlet pipe 220 housing

221: guide bar 221a: screw

221b nut 222 hollow part

223: home 224: O-ring

225 floor 226 injection pipe

227: Home 228: O-Ring

229: housing spring 230: nozzle

231: top plate 231a: gas discharge hole

232: Shoring 232a: Screw

232b: nut 233: bottom plate

233a: home 233b: o-ring

234: nozzle spring 240: support plate

241: housing receiving hole 242: guide bar receiving hole

P: Flange

Claims (4)

delete The contact pipe forming the path for transporting the argon gas into the ladle is coupled and closely contacted by the pressing operation, and the contact plate acts as a coupler, and is disposed to face the same axis with the contact plate, thereby contacting the contact plate. And a nozzle for opening and closing the argon gas supply passage while vertically flowing, and a nozzle spring for providing an elastic force for vertically flowing the nozzle, and forming a path for transferring argon gas to the bottom. And a housing spring for assisting the up and down flow of the housing when the contact plate is in contact with the outer diameter of the housing, and a support plate for supporting the housing while flowing up and down by the elastic force of the housing spring on both sides. In the gas injection device, The nozzle is an argon gas automatic injection device for steelmaking ladle, characterized in that the upper plate and the lower plate formed with a supply path of the argon gas and the lower plate is integrally coupled to each other by a support so as to have a gap. According to claim 2, Argon gas automatic injection device for steelmaking ladle, characterized in that the upper surface of the housing and the lower plate of the nozzle is formed an O-ring for airtight. The argon gas for steelmaking ladle according to claim 2, wherein the nozzle spring is formed of a compression spring, and the housing spring is formed of a leaf spring to absorb damage when the ladle is seated to prevent damage. Auto Injection Device.

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