KR20200067543A - Device for opening molten metal outlet of ladle - Google Patents

Abstract

Provided is an opening apparatus for an opening unit of a ladle. The present invention seeks to provide the opening apparatus for the opening unit of the ladle, which allows a clogged portion of the opening unit to be safely opened when the opening unit at the bottom of the ladle is clogged during a process. The opening apparatus for the opening unit of the ladle according to the present invention comprises: a chamber filled with a reaction gas; a heater containing a reactant for heating the reaction gas; a rupture plate ruptured by expansion of the reaction gas; and a striking body accelerated by an inflation pressure of the reaction gas to strike the clogged portion of the opening unit.

Description

Opening device of the opening part of the ladle {DEVICE FOR OPENING MOLTEN METAL OUTLET OF LADLE}

The present invention relates to an opening device for an opening of a ladle.

Generally, a ladle is used in the steelmaking and performance process to transport molten steel.

When the opening of the ladle, through which the molten steel is discharged, is filled with a ladle filler and the molten steel is received in the ladle, the upper layer portion of the ladle filler, which is the contact portion between the ladle filler and the molten steel, is sintered to form a sintered layer.

When the gate is opened to discharge the molten steel, the sintered layer is destroyed by the pressure of the molten steel, and the molten steel is discharged through the opening by its own weight.

However, if the molten steel is held in the ladle for a long time due to process reasons, the thickness of the sintered layer of the ladle filler becomes thick, or when foreign matters such as refractory materials and the like are mixed in the opening, the phenomenon that molten steel does not discharge even when the gate is opened.

When the molten steel is not discharged in this way, the operator opens the clogged portion using an oxygen pipe.

The reason for this opening work is that the worker is not safe due to the scattering of molten steel, and since the shroud nozzle cannot be used, the cleanliness of molten steel cannot be maintained.

In order to avoid this risk, the molten steel is transferred to a new ladle and reprocessed. In the case of reprocessing, the operation time becomes longer, the cost of subsidiary materials increases, and continuous operation may be stopped.

The present invention seeks to provide an opening device for an opening of a ladle so that when the opening of the bottom of the ladle is blocked during the process, the blocked area of the opening is safely opened.

The opening device of the opening of the ladle according to the embodiment of the present invention is a device for opening the opening by being installed on a shroud nozzle coupled to the opening when the opening of the ladle through which molten steel is discharged is blocked.

The opening device of the opening portion of the ladle may include a chamber inserted into the shroud nozzle and filled with the reaction gas, and a heater inserted into the chamber and installed with the reactant for heating the reaction gas through an exothermic reaction. have.

In addition, the opening device of the opening portion of the ladle is installed at the upper end of the chamber, and the rupture plate is ruptured by the expansion of the reaction gas, and is disposed on the rupture plate and accelerated by the expansion pressure of the reaction gas to strike the blocked portion of the opening It may include a striking body for.

The reaction gas may consist of one gas selected from liquid carbon dioxide (CO ₂ ), argon gas, nitrogen gas, and helium gas.

An electric igniter may be connected to the heater to electrically initiate the exothermic reaction of the reactants.

A guide pipe for guiding the striking body to the blocked portion of the opening may be installed in the upper part of the chamber.

A housing for accommodating the electric igniter may be installed in the lower part of the chamber.

At the upper end of the striking body, a pointed warhead may be disposed.

At least one support bracket may be installed inside the shroud nozzle to support the reaction force of the striking body.

The material of the chamber, heater, rupture plate, striking body, guide pipe, housing, and support bracket may be made of steel.

According to the embodiment of the present invention, by using the opening device of the opening portion of the ladle to open the blocked portion of the opening portion, it is possible to safely open the blocked portion of the opening portion and discharge molten steel while maintaining the cleanliness of the molten steel. It can prevent downtime and reduce costs.

1 is a schematic configuration diagram showing an installation state of an opening device of an opening part of a ladle according to an embodiment of the present invention.
2 is a configuration diagram of an opening device of an opening of a ladle according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains can easily practice. As those of ordinary skill in the art to which the present invention pertains can easily understand, the embodiments described below may be modified in various forms without departing from the concept and scope of the present invention. Where possible, the same or similar parts are indicated by the same reference numerals in the drawings.

The terminology used hereinafter is for reference only to specific embodiments, and is not intended to limit the invention. The singular forms used herein also include plural forms unless the phrases clearly indicate the opposite. As used herein, the meaning of “comprising” embodies certain properties, regions, integers, steps, actions, elements and/or components, and other specific properties, regions, integers, steps, actions, elements, components and/or groups It does not exclude the existence or addition of.

All terms including technical terms and scientific terms used hereinafter have the same meaning as those generally understood by those skilled in the art to which the present invention pertains. Terms defined in the dictionary are additionally interpreted as having meanings consistent with related technical documents and currently disclosed contents, and are not interpreted in an ideal or very formal sense unless defined.

1 is a schematic configuration diagram showing an installation state of an opening device of an opening part of a ladle according to an embodiment of the present invention, and FIG. 2 is a configuration of an opening device of an opening part of a ladle according to an embodiment of the present invention It is.

Referring to Figures 1 and 2, the opening device of the opening of the ladle according to an embodiment of the present invention when the opening 13 provided on the bottom of the ladle 10 from which the molten steel 11 is discharged is blocked It is a device to safely open the blocked part of (13).

The opening device may be installed in a shroud nozzle 20 that is inserted into the opening 13 of the ladle 10 to prevent oxidation of molten steel.

A gate 30 for opening and closing the opening 13 may be installed in the shroud nozzle 20.

The opening device may include a chamber 100, a heater 200, a rupture plate 300, a striking body 400, and an electric igniter 500.

The chamber 100 is inserted into the shroud nozzle 20 and filled with a reactant gas that expands when it rises above a set temperature.

In addition, the heater 200 immersed in the reactant 210 for heating the reaction gas 110 to a predetermined temperature or more by an exothermic reaction may be installed inside the chamber 100.

A rupture plate 300 that is ruptured when the reaction gas 110 expands and reaches a set pressure may be installed at an upper end portion of the chamber 100.

In addition, when the rupture plate 300 is ruptured on the upper portion of the rupture plate 300, it is accelerated by the expansion pressure of the reaction gas 110 to strike the clogged portion of the opening portion 13, thereby hitting the opening 400 Can be installed.

In addition, an electric igniter 500 may be installed at a lower end of the chamber 100 to be connected to the heater 200 and to electrically initiate an exothermic reaction of the reactant 210 of the heater 200.

A guide pipe 600 for accurately guiding the striking body 400 to the center of the blocked portion of the opening 13 may be installed in the upper portion of the chamber 100 in communication.

In addition, a housing 700 for accommodating the electric igniter 500 may be installed in the lower portion of the chamber 100 in communication.

The chamber 100 may be formed of a cylindrical tube having a set length and diameter so as to fill the reaction gas 110 with a set amount.

The reaction gas 110 is raised to a set temperature by an exothermic reaction of the heater 200 and can be easily expanded to a set pressure, and may be made of safe and inexpensive liquid carbon dioxide (CO ₂ ).

In addition, the reaction gas 110 may be made of one gas selected from argon gas, nitrogen gas, and helium gas in addition to liquid carbon dioxide.

When the heater 200 is ignited by the electric igniter 500, the reaction gas 110 is heated to a set temperature by an exothermic reaction.

The heater 200 is arranged in a vertical direction (Y direction in FIG. 2) from the lower end of the chamber 100 so that the reaction gas 110 inside the chamber 100 can be easily heated, and in the center of the chamber 100 Can be deployed.

The rupture plate 300 may have a thickness set so that the reaction gas 110 may rupture when it expands above a set pressure.

That is, the pressure applied to the striking body 400 can be controlled by adjusting the thickness of the bursting plate 300.

The striking body 400 may be disposed with a gap between the bursting plate 300 so that it can be easily fired by the bursting of the bursting plate 300.

In addition, the striking body 400 may have a diameter smaller than the diameter of the guide pipe 600 so that it can be easily fired by the expansion pressure of the reaction gas 110.

By adjusting the size and weight of the striking body 400, it is possible to control the amount of impact applied to the blocked portion of the opening 13, that is, the impact energy.

A sharp-shaped warhead portion 410 may be disposed at an upper end portion of the striking body 400 so as to accurately hit the blocked portion of the opening portion 13.

The electric igniter 500 may be connected to the lower end of the heater 200 outside the lower end of the chamber 100.

A remote control (not shown) may be wirelessly connected to the electric igniter 500 to remotely control the operation of the electric igniter 500.

By adjusting the length of the guide pipe 600, it is possible to adjust the impact speed of the striking body 400.

In addition, upper and lower support brackets 800 and lower support brackets 810 may be installed on the upper and lower portions of the shroud nozzle 20 to support the reaction force when the striking body 400 is accelerated.

The upper support bracket 800 may be installed on the upper portion of the chamber 100 to more firmly support the repulsive force of the striking body 400, and the lower support bracket 810 may be installed on the lower portion of the chamber 100.

That is, the upper support bracket 800 may be connected to a plurality of intervals set between the upper portion of the guide pipe 600 and the inner surface of the shroud nozzle 20.

In addition, a plurality of lower support brackets 810 may be connected at predetermined intervals between the lower end of the housing 700 and the inner surface of the shroud nozzle 20.

Materials of the chamber 100, the heater 200, the rupture plate 300, the striking body 400, the guide pipe 600, the housing 700, and the upper and lower support brackets 800 and 810 are molten steel discharge furnace steel When dissolved and mixed in, all may be made of steel or the like to minimize changes in molten steel components.

Hereinafter, with reference to Figures 1 and 2, the operation of the opening device of the opening of the ladle according to an embodiment of the present invention will be described.

When the opening 13 of the bottom of the ladle 10 is blocked during the steelmaking and playing process, the shroud nozzle 20 equipped with the opening apparatus according to an embodiment of the present invention is mounted on the opening 13.

That is, the opening device is inserted into the central portion of the shroud nozzle 20, and is supported by the shroud nozzle 20 by the upper support bracket 800 and the lower support bracket 810.

As described above, when the opening device is mounted in the shroud nozzle 20, when the electric igniter 500 is operated remotely using a remote controller (not shown), the electric igniter 500 starts to react electrically.

As the electrical reaction of the electric igniter 500 is initiated, an exothermic reaction of the reactant 210 contained inside the heater 200 occurs, and a reaction gas (eg, liquid carbon dioxide (CO) in the chamber 100 is generated by the exothermic reaction. ₂ )) 110 is heated.

When the reaction gas 110 is heated to rise to a set temperature and is boosted and expanded to a set pressure, the rupture plate 300 is ruptured by the expansion of the reaction gas 110, and the striking body 400 is accelerated (launched). .

At this time, the reaction force generated by the acceleration of the striking body 400 is supported by the upper support bracket 800 and the lower support bracket 810 installed in the shroud nozzle 20.

Then, the striking body 400 is accelerated (launched) and guided by the guide pipe 600 while striking the clogged portion of the opening 13 to apply an impact to the center of the clogged portion of the opening 13 to open it. .

As described above, when the blocked portion of the opening portion 13 is opened by the impact of the hitting body 400, the sintered layer is destroyed and the molten steel 11 is safely discharged through the shroud nozzle 20 by its own weight.

At this time, the opening device of the opening of the ladle is dissolved in molten steel while being swept and discharged together with the molten steel 11 discharged through the shroud nozzle 20.

The material of the chamber 100, the heater 200, the rupture plate 300, the striking body 400, the guide pipe 600, the housing 700, and the upper and lower support brackets 800 and 810 are all made of steel. Therefore, even if the opening device of the opening portion of the ladle is dissolved and mixed in the molten steel, the change in the molten steel component can be minimized.

As described above, by using the opening device of the opening portion of the ladle to open the blocked portion of the opening portion, the blocked portion of the opening portion can be safely opened, and the molten steel can be discharged while maintaining the cleanliness of the molten steel. It can prevent and reduce the cost as much as possible.

100: chamber
110: reaction gas
200: heater
300: bursting disc
400: hitting body
500: electric igniter
600: guide pipe

Claims (8)

When the opening portion of the ladle through which molten steel is discharged is blocked, it is installed on a shroud nozzle coupled to the opening portion, and as a device for opening the opening portion,
The chamber is inserted into the shroud nozzle and filled with a reaction gas,
A heater installed inside the chamber and containing a reactant for heating the reaction gas by an exothermic reaction,
A rupture plate installed at the upper end of the chamber and ruptured by the expansion of the reaction gas,
It is disposed on the upper portion of the rupture plate, accelerated by the expansion pressure of the reaction gas hitting body for striking the clogged portion of the opening
Opening device of the opening of the ladle comprising a. According to claim 1,
The reaction gas is a liquid carbon dioxide (CO ₂ ), argon gas, nitrogen gas, helium gas is made of one gas selected, the opening device of the opening of the ladle. According to claim 2,
The heater is connected to an electric igniter that electrically initiates the exothermic reaction of the reactant. According to claim 1,
Opening device of the opening portion of the ladle, a guide pipe is provided in communication with the upper portion of the chamber to guide the hitting body to the blocked portion of the opening portion. The method of claim 4,
In the lower portion of the chamber, a housing for accommodating the electric igniter is installed in communication, an opening device for an opening of a ladle. The method of claim 4,
Opening device of the opening of the ladle, a pointed warhead is disposed on the upper end of the striking body. The method of claim 5,
At least one support bracket for supporting the repulsive force of the striking body is installed inside the shroud nozzle, the opening device of the opening of the ladle. The method of claim 7,
The chamber, the heater, the rupture plate, the striking body, the guide pipe, the housing, and the material of the support bracket is made of steel, the opening device of the opening of the ladle.

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