KR101367301B1 - Flux feeding apparatus and molten mold flux feeding method - Google Patents

Abstract

The present invention relates to a flux supply device and a supply method for supplying a flux through a pressure control method through a gas supply,
Flux supply apparatus according to an embodiment of the present invention is a flux supply device which is installed on the upper side of the mold for receiving molten steel to supply the flux to the mold, the flux supply pipe is installed on one side, the crucible for storing the supplied flux ; And a gas supply unit configured to increase a pressure inside the crucible and supply a gas to discharge the flux to the outside through the pressure increase.

Description

Flux feeding device and feeding method {FLUX FEEDING APPARATUS AND MOLTEN MOLD FLUX FEEDING METHOD}

The present invention relates to a flux supply device and a supply method, and more particularly, to a flux supply device and a supply method for supplying a flux through a pressure control method through a gas supply.

Generally, when molten steel is supplied into a mold during continuous casting of steel, not only molten steel but also an auxiliary mold flux is introduced. Mold flux is generally introduced into a solid state such as powder or granules and melted by the heat generated in the molten steel supplied into the mold to control heat transfer between the molten steel and the mold and to improve lubrication ability.

1 is a schematic cross-sectional view showing a conventional flux supply apparatus.

As shown in FIG. 1, a conventional flux supply apparatus 10 includes a crucible 30 made of a graphite-based material for receiving a mold flux source 20, and a mold flux dissolved from the mold flux source 20. Including a heating means 40 such as a heating wire provided around the crucible 30 to melt the mold flux charged in the crucible 30, and a discharge pipe for discharging the molten mold molten from the crucible 30 And a stopper 60 for controlling the flow rate of the liquid mold flux 3 discharged by opening and closing the discharge nozzle 50 and the discharge nozzle 50. Here, reference numeral 70 denotes a mold, 80 denotes an immersion nozzle for guiding and discharging molten steel in a tundish (not shown) to the mold 70, and 90 denotes a water surface cover.

However, in the related art, since the stopper 60 for controlling the discharge of the mold flux is in contact with the mold flux of a high temperature state inside the crucible 30, the stopper 60 made of a metal material is thermally expanded by receiving the high temperature of the mold flux and thus the shape is changed. There was a problem of deformation.

In addition, as the flux supply operation for a long time is progressed, the stopper 60 is gradually thermally deformed to cause the mold flux outlet to not be accurately closed, and thus the supply amount control of the mold flux cannot be performed properly. There was a problem that the productivity is lowered.

Korean Patent Publication No. 10-2010-0074904

One technical problem of the present invention is to provide a flux supply device and a supply method for supplying the flux to the mold side through a pressure control method through a gas supply.

In addition, one technical problem of the present invention is to provide a flux supply device and a supply method that can control the flux discharge while having a simpler structure.

Flux supply apparatus according to an embodiment of the present invention,

A flux supply device installed on an upper side of a mold accommodating molten steel and supplying flux to the mold, the flux supply pipe being installed on one side, and a crucible for storing the supplied flux; And a gas supply unit configured to increase a pressure inside the crucible and supply a gas to discharge the flux to the outside through the pressure increase.

The gas supply unit, the gas storage tank in which the inert gas is stored; A gas supply pipe connected to the gas storage tank to form a path through which the inert gas flows; And a solenoid valve installed at the gas supply pipe to electrically control a supply pressure of the inert gas.

In addition, the insulating wall is installed to surround the crucible; And a casing which surrounds the insulating wall to form an exterior, wherein the gas includes at least one of an inner space of the crucible, a space between the crucible and the insulating wall, and a space between the insulating wall and the casing. It can be supplied above.

The heat insulating wall may be provided with a heating heater for heating the flux stored in the crucible and the flux discharged to the outside of the crucible.

The flux stored inside the crucible may include a flux moving tube including an upward moving tube in which the flux is moved upward by a pressure, and an upper end portion communicating with the upward movement tube, and a lower movement tube having a lower end exposed to the outside of the casing.

An air vent pipe communicating with the flux moving pipe and having an upper end exposed to the outside of the casing to supply outside air to the flux moving pipe may be included.

Preferably, the crucible and the flux moving tube are made of a metal oxide. Here, the oxidation-resistant metal is preferably a stainless material.

It may include a temperature sensor for measuring the temperature of the flux stored in the crucible.

A flux discharge flow rate meter for measuring the discharge flow rate of the flux is further provided, and receives the measured temperature of the flux through the temperature sensor and compares it with a set reference value to control the heating value of the heating heater and the flux discharge flow rate meter A control unit may be further provided to receive the measured flow rate value to control the supply of the gas.

Flux supply method according to an embodiment of the present invention,

A flux supply method for supplying flux stored in a crucible to an outside of the crucible, the method comprising: increasing a pressure inside the crucible; Supplying flux to the outside of the crucible by moving the flux stored in the crucible up and down by the increased pressure.

In the process of increasing the pressure inside the crucible, the inert gas is supplied to the inside of the crucible to increase the pressure inside the crucible, and the flux stored inside the crucible is moved up and down by the increased pressure to move the flux outside the crucible. In the process of supplying, the flux is raised through the upward movement pipe installed in the crucible and the elevated flux is lowered through the downward movement pipe installed in communication with the upward movement pipe.

The supply of the flux may be controlled by supplying outside air to the upward movement pipe to prevent the flux from rising.

According to the embodiment of the present invention as described above, by supplying the flux to the mold side through the pressure control method through the gas supply, the supply of the flux can be controlled efficiently and accurately even after a long time operation. In addition, it is possible to control the flux supply efficiently with a simpler structure by omitting a device such as a stopper for controlling the flux supply. In addition, it is possible to omit a device such as a stopper to prevent a decrease in productivity due to the problem of deformation of the stopper due to long use.

1 is a front sectional view showing a flux supply apparatus according to the prior art,
Figure 2 is a front sectional view showing a flux supply apparatus according to an embodiment of the present invention,
3 is a flowchart illustrating a flux supply method according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be apparent to those skilled in the art that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know. Wherein like reference numerals refer to like elements throughout.

Figure 2 is a front sectional view showing a flux supply apparatus according to an embodiment of the present invention.

As shown in Figure 2, the flux supply apparatus according to an embodiment of the present invention, which is installed on the upper side of the mold 70 for receiving molten steel to supply the flux to the mold 70, one side of the flux supply pipe ( 100 is installed and the crucible 310 for storing the supplied flux, and the gas supply unit 500 for supplying the gas to discharge the flux to the outside through an increase in pressure by increasing the pressure inside the crucible (310) 520, 520 , 530). Meanwhile, in the related art, a separate device such as a stopper device and a sliding gate is provided to supply and shut off the flux, whereas the present invention increases the pressure inside the crucible by gas supply, and discharges the flux through the pressure increase. It is supplied to 70. That is, according to the embodiment of the present invention, it is not necessary to install a separate device for the on / off of the flux supply, it is possible to design a simple and compact structure. On the other hand, the flux described herein may be powder or liquid type. In particular, the flux may be a molten mold flux.

On the other hand, the flux supply apparatus according to the present embodiment, a triple structure including a heat insulating wall 320 installed to surround the crucible 310, and a casing 330 to form an appearance while surrounding the heat insulating wall 320 It may be made of. Here, it is preferable that a predetermined or more space is formed between the crucible 310 and the heat insulating wall 320, and the heat insulating wall 320 and the casing 330 for supplying an inert gas, which will be described later.

The crucible 310 is a place where a predetermined amount of flux is supplied and stored, one side is provided with a flux supply pipe 100 for receiving the flux from the flux storage tank (not shown). Meanwhile, sintered materials such as graphite and refractory materials have been mainly used as materials for constituting the crucible 310 itself or constituting the inner wall of the crucible 310, but such sintered materials react with the flux. There has been a problem of chemical erosion or of changing the composition of the flux.

In order to solve this problem, in this embodiment, a portion in direct contact with the flux is applied as a material of the oxidation resistant metal. In detail, the crucible 310 and the flux moving pipes 400 (410 and 420) described below, which form a discharge path of the flux, are applied to the oxidizing metal. Specifically, the oxidizing metal is not easily eroded or corroded to the flux. It is preferable to apply to a stainless-based material.

The heat insulation wall 320 is to insulate the flux to the outside to prevent the temperature drop of the flux stored in the crucible 310 to the maximum, for example, it may be made of a ceramic-based material. The insulation wall is installed to surround the crucible 310 to prevent the temperature drop of the flux stored in the crucible 310 to the maximum.

Meanwhile, heating heaters 340: 341 and 342 for heating the flux stored in the crucible 310 and the flux discharged to the outside of the crucible 310 are installed on the heat insulation wall 320. Specifically, the heating heater 340 is to prevent the temperature drop of the flux as much as possible until the flux is supplied to the mold 70, the first installed on the side of the crucible 310 to heat the flux stored in the crucible 310 A heating heater 341 and a second heating heater 342 installed above the crucible 310 to heat the flux discharged from the crucible 310 are included. Here, the first and second heating heaters 341 and 342 can control the heating temperature by the controller 700 to be described later.

The casing 330 is installed to surround the heat insulating wall 320 to form an appearance, it is preferable that the casing 330 is made of a steel bar of the internal pressure to withstand the pressure of the inert gas sufficiently.

In the crucible 310 and the heat insulating wall 320, the flux inside the crucible 310 is moved upwardly and discharged from the crucible 310 and then lowered again to form a flux movement path so as to be discharged to the outside of the casing 330. Moving tubes 400 and 410 and 420 are installed. Here, the flux moving tube 400 is formed in a substantially n-shape, the lower end is bent to communicate with the upward movement pipe 410 is installed so as to be immersed in the flux stored in the crucible 310, the upper end and the upward movement pipe 410 The lower end includes a lower movable pipe 420 exposed to the outside of the casing 330.

The present embodiment has a structure in which the flux is discharged by the supply of the gas as described above, and the gas includes the internal space of the crucible 310, the space between the crucible 310 and the heat insulating wall 320, and the heat insulating wall 320. And at least one of the spaces between the casing 330 is supplied. That is, even when gas is supplied to any one of the three spaces, an increase in the pressure inside the crucible 310 is generated, whereby flux can be discharged by the increase in pressure. However, it is more preferred that the gas is fed directly into the crucible 310 in order to generate a more efficient pressure increase by supplying the gas so that the flux is expelled from the crucible 310 quickly.

Gas supply units 500 (510, 520, 530) supplying gas for discharge of the flux are connected to the gas storage tank 510 in which the inert gas is stored and the gas storage tank 510 to flow the inert gas. And a solenoid valve 530 installed at the gas supply pipe 520 to electrically control the supply pressure of the inert gas. In FIG. 2, the end of the gas supply pipe 520 is connected to the crucible 310, but the present invention is not limited thereto. The gas supply pipe 520 may include a space between the casing 330 and the heat insulation wall 320 and the heat insulation wall 320. ) And the crucible 310 can be installed to communicate with any of the spaces.

That is, in an exemplary embodiment of the present invention, when an inert gas is supplied into the crucible 310 via the gas supply pipe 520, an increase in pressure inside the crucible 310 occurs and an increase in pressure causes the inside of the crucible 310 to be increased. The flux is discharged to the outside of the casing 330 after sequentially passing through the upward movement pipe 410 and the downward movement pipe 420.

Meanwhile, an air vent pipe 430 communicating with the flux moving pipe 400 and having an upper end exposed to the outside of the casing 330 may be further installed. The air vent pipe 430 allows the outside air to flow into the flux moving pipe 400 to allow more accurate supply control of the flux. Specifically, when the outside air is introduced into the air vent pipe 430, the pressure balance with the flux in the upward movement pipe 410, the pressure balance is prevented from rising any more in the upward movement pipe 410. As a result, the flux may not pass through the descending moving tube 420, and thus the flux may be stopped more quickly. At this time, the solenoid valve 530 is operated through the control unit 700 may stop the supply of inert gas. When the supply of outside air through the air vent pipe 430 is stopped, the pressure is increased again by the inert gas supplied through the gas supply pipe 520 so that the flux is moved to the outside via the rising moving pipe 410 and the falling moving pipe 420. May be discharged.

According to an embodiment of the present invention, a temperature sensor 600 for measuring the flux temperature inside the crucible 310 may be further installed. The temperature sensor 600 may be installed to pass through the casing 330, the heat insulation wall 320, and the crucible 310, and may be installed such that a lower end thereof is located near the bottom of the crucible 310. On the other hand, the control unit 700 receives the measurement temperature of the flux through the temperature sensor 600, and compares it with a predetermined reference value, and then appropriately control the amount of heat generated by the heating heaters 340: 341, 342 crucible ( 310) Adjust the temperature of the flux inside.

On the other hand, the flux moving pipe 400 may be further provided with a flux discharge flow rate (800) for measuring the discharge flow rate of the flux, the control unit 700 receives the measured flow rate value from the flux discharge flow rate (800) the solenoid The opening and closing of the valve 530 is controlled to control the supply amount of the inert gas, thereby adjusting the discharge flow rate of the flux.

According to the embodiment of the present invention, by supplying the flux to the mold side through the pressure control method through the gas supply it is possible to control the supply of the flux efficiently and accurately even after a long time operation. In addition, it is possible to control the flux supply efficiently with a simpler structure by omitting a device such as a stopper for controlling the flux supply. In addition, it is possible to omit a device such as a stopper to prevent a decrease in productivity due to the problem of deformation of the stopper due to long use.

Next, a flux supply method according to an embodiment of the present invention will be described with reference to FIG. 3. 3 is a flowchart illustrating a flux supply method according to an embodiment of the present invention. In this embodiment, the flux may be, for example, a molten mold flux, but is not limited thereto.

First, the pressure inside the crucible is increased. In other words, an internal space of the crucible 310, a space between the crucible 310 and the heat insulating wall 320, and a space between the heat insulating wall 320 and the casing 330. The pressure inside the crucible is increased by supplying an inert gas into at least one of the spaces. In particular, the inert gas is preferably supplied directly into the crucible 310 in order to effectively generate the pressure increase by the inert gas supply.

Then, the flux is increased by the increased pressure inside the crucible (S20). That is, the flux is raised through the upward movement pipe 410 installed in the crucible and the downward movement pipe 420 installed in communication with the upward movement pipe. The flux is lowered to supply flux to the outside of the crucible (eg, mold 70).

At this time, it is determined whether to continue to supply the flux (S30). That is, when continuing the continuous casting process, the flux is supplied, and when the continuous casting process is to be stopped, the flux is stopped.

In the case of continuously supplying the flux, the air vent pipe 430 is turned off in order to prevent external air from being supplied to the upward movement pipe 410 through the air vent pipe 430 (S40). 410) to block the air vent pipe so that outside air is not supplied.

When the supply of the flux is to be stopped, the air vent pipe 430 is turned on so that outside air is supplied to the upward movement pipe 410 through the air vent pipe 430 (S50). Open the air vent pipe to supply outside air. When the outside air flows into the air vent pipe 430, pressure is balanced with the flux in the upward movement pipe 410. The pressure balance prevents the flux from rising any more in the upward movement pipe 410. As a result, the flux cannot pass through the descending movement pipe 420, thereby preventing the flux from being discharged to the outside.

When the air vent pipe 430 maintains the off state, the flux raised through the upward movement pipe 410 is lowered by the downward movement pipe 420 installed in communication with the upward movement pipe to be supplied to the outside of the crucible.

As described above with reference to the drawings illustrating a flux supply apparatus and a supply method according to the present invention, the present invention is not limited by the embodiments and drawings disclosed herein, within the scope of the technical spirit of the present invention Of course, various modifications may be made by those skilled in the art.

100: flux supply pipe 310: crucible
320: insulation wall 330: casing
340: heating heater 400: flux moving tube
410: upward movement pipe 420: downward movement pipe
430: air vent pipe 500: gas supply unit
600: temperature sensor 700: control unit

Claims (13)

A flux supply device which is installed on the upper side of the mold for receiving molten steel to supply the flux to the mold,
Flux supply pipe is installed on one side, the crucible for storing the supplied flux;
A casing which forms an appearance while surrounding the crucible;
A gas supply unit configured to increase a pressure inside the crucible and supply a gas to discharge the flux to the outside through the increase in pressure;
A temperature sensor for measuring a temperature of the flux stored in the crucible;
The inner and outer sides of the crucible are in communication with each other, and the flux inside the crucible is moved up and down again to be discharged to the outside of the casing to be installed in a flux moving tube which forms a movement path of the flux, and the discharge flow rate of the flux A flux discharge flow meter for measuring the flow rate; And
It is provided on the outside of the crucible, and receives the measured temperature of the flux through the temperature sensor and compares with the set reference value to control the heating value of the heating heater and receiving the measured flow rate value of the flux discharge flow meter to supply the gas And a control unit for controlling the
The flux moving tube includes a rising moving tube in which the flux stored inside the crucible is moved up by a pressure, and a lowering moving tube bent so that its upper end is in communication with the rising moving tube, and a lower end thereof is exposed to the outside of the casing.
The crucible and the flux moving tube are formed of an oxidation resistant metal that is not easily eroded or corroded to the flux.
The heating heater is installed on the side of the crucible and the first heating heater for heating the flux stored in the crucible,
And a second heating heater installed above the crucible to heat the flux discharged from the crucible.
The method of claim 1,
The gas-
A gas storage tank in which an inert gas is stored;
A gas supply pipe connected to the gas storage tank to form a path through which the inert gas flows; And
And a solenoid valve installed at the gas supply pipe to electrically control a supply pressure of the inert gas.
The method of claim 1,
Insulating wall is installed to surround the crucible; further comprising,
The gas is supplied to at least one of the inner space of the crucible, the space between the crucible and the heat insulating wall, and the space between the heat insulating wall and the casing.
delete delete 4. The method according to any one of claims 1 to 3,
And an air vent pipe communicating with the flux moving tube and having an upper end exposed to the outside of the casing to supply outside air to the flux moving tube.
delete The method of claim 1,
The oxidation-resistant metal is a flux supply device of a stainless series material.
delete delete Flux supply method for supplying the flux stored in the crucible to the outside of the crucible,
Increasing the pressure inside the crucible;
Supplying the flux to the outside of the crucible by raising the flux through an upward moving tube installed in the crucible by an increased pressure and lowering the elevated flux through a downward moving tube installed in communication with the upward moving tube; And
Determining whether to continue to supply the flux;
In the case of continuously supplying the flux, the air vent pipe is turned off in order to prevent external air from being supplied into the upward movement pipe.
In the case where the supply of the flux is to be stopped, the air vent pipe is turned on to supply the outside air into the upward movement pipe so that the outside air is pressure-balanced with the flux in the upward movement pipe so that the flux rises. How to supply flux to prevent.
The method of claim 11,
The increasing of the pressure inside the crucible may include supplying an inert gas into the crucible to increase the pressure inside the crucible.
delete

Images