KR101315354B1 - Outlets nozzle and Apparatus for supplying melt mold flux using the same - Google Patents

Abstract

The present invention relates to an outlet nozzle for injecting the flux supplied to the molten steel of the molten steel during the continuous casting operation in advance to the outside of the mold and injecting the flux into the mold, in particular the flux melt supply apparatus according to an embodiment of the present invention The supply apparatus is an apparatus for melting flux injected into a mold, comprising: a melting furnace for melting the flux and having an outlet at a side thereof; An outlet nozzle mounted to an outlet of the melting furnace, provided with a heating heater for heating the melted flux, and having a temperature sensor for measuring the temperature of the melted flux; One side is installed to be located below the outlet nozzle, the other side includes an injection nozzle extending in the upper direction of the mold.

Description

Outlet nozzle and Apparatus for supplying melt mold flux using the same}

The present invention relates to an outlet nozzle and a flux melt supply device using the same, and more particularly, an outlet nozzle for injecting a flux supplied to a molten steel into the mold by injecting the flux supplied to the molten steel in a continuous casting operation in advance into a mold and a flux melt using the same. It relates to a supply device.

In general, in a continuous casting process, when molten steel is solidified in a mold, mold flux is introduced into the molten steel at room temperature for the purpose of lubrication, thermal insulation, inclusion separation and collection of generated gas. In this case, inevitably cooling occurs at the hot water surface of the upper part of the mold, causing a problem in that the temperature of the meniscus is lowered and the hook is excessively grown. As a result, the surface is irregularly solidified and the inclusion of the inclusions and separation of the generated gas is hindered, and the oscillation mark depth of the cast is increased, which adversely affects the surface quality. In addition, due to the moisture in the mold flux introduced at room temperature, a gas such as hydrogen moves into the molten steel and the gas is confined between the mold and the solidification cell during solidification, thereby causing a problem of deteriorating the surface quality of the final product.

In order to prevent this, a method of injecting the mold flux into the mold while the mold flux is melted from the outside of the mold has recently been proposed, and this suggests a method of injecting the molten mold flux melted from the mold furnace into the mold. Implemented with an injection tube.

The injection tube was installed at the outlet side of the furnace to provide the molten mold flux to fall on top of the injection tube constantly. However, the melt mold flux passing through the outlet of the furnace contacted the atmosphere, causing the temperature to drop and gradually causing the outlet to be clogged. It was.

Accordingly, even if the outlet of the melting furnace is completely blocked or not completely blocked, the flow of molten mold flux is not kept constant due to the presence of the mold flux solidified at the outlet. There was a problem that occurred.

Embodiments of the present invention provide a flux melt feeder that can melt a mold flux outside of a mold and can smoothly transfer the mold flux to the mold without lowering the temperature of the molten mold flux.

In addition, when the molten mold flux discharged from the melting furnace is discharged to the injection nozzle, the molten mold flux in the melting nozzle of the melting furnace is provided to prevent the outlet nozzle from clogging or changing the direction of the injection flow provides an outlet nozzle of the furnace. .

The outlet nozzle according to the embodiment of the present invention is an outlet nozzle installed at the outlet of the melting furnace for melting the flux, the nozzle body is formed of a refractory, there is formed a flow path communicating both ends therein; A heating heater embedded in the nozzle body to be adjacent to the flow path; And a temperature sensor passing through the nozzle body and exposed to the flow path.

A connection part connected to the melting furnace is formed at one end of the nozzle body, and an auxiliary nozzle part is formed at the other end of the nozzle body to guide the discharge direction of the molten flux while extending the flow path.

The flow path is characterized in that the inclined downward from one end of the nozzle body in the other end direction.

Flux melt supply apparatus according to an embodiment of the present invention is a device for melting the flux injected into the mold, the melting furnace for melting the flux, the outlet is formed on the side; An outlet nozzle mounted to an outlet of the melting furnace, provided with a heating heater for heating the melted flux, and having a temperature sensor for measuring the temperature of the melted flux; One side is installed to be located below the outlet nozzle, the other side includes an injection nozzle extending in the upper direction of the mold.

The outlet nozzle is characterized in that the auxiliary nozzle portion for guiding the discharge direction of the molten flux is formed.

And a control unit for controlling the operation of the heating heater in response to the temperature of the melted flux measured by the temperature sensor.

The injection nozzle is characterized in that the injection port is formed in which the molten flux falling from the outlet nozzle is injected into the upper portion of one side, the discharge port for discharging the molten flux in the mold on the other side or the lower side.

The injection nozzle is characterized in that the thermal insulation cover for insulating the molten flux is installed.

And tilting means for tilting the melting furnace.

The tilting means includes a support housing for supporting the melting furnace; A tilt shaft installed at an intermediate lower region of the support housing to support both ends of the support housing in a vertical direction; It is installed on at least one lower area of the support housing and includes a tilt driving unit for lifting up and down one side of the support housing.

A movable plate provided to be movable to install the melting furnace and the injection nozzle, the moving means comprising: a base plate on which a plurality of wheels are mounted; It is installed on the base plate includes at least one support frame for supporting the injection nozzle.

According to the embodiment of the present invention, by controlling the temperature of the mold flux melted and discharged from the melting furnace, it is possible to prevent the nozzle clogging by the mold flux in the outlet nozzle to ensure a stable operation in the entire continuous casting process.

In addition, by forming an auxiliary nozzle portion for controlling the injection flow direction of the molten mold flux at the outlet nozzle of the melting furnace, it is possible to prevent the molten mold flux from scattering, thereby preventing an operation accident due to the mold flux scattering.

1 is a perspective view showing a flux melt supply apparatus according to an embodiment of the present invention,
Figure 2 is a cross-sectional view showing the outlet nozzle of the melting furnace according to an embodiment of the present invention,
Figure 3 is a longitudinal sectional view showing the outlet nozzle of the melting furnace according to an embodiment of the present invention,
4a and 4b is an operating state diagram showing the operating state of the flux melt supply apparatus 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.

1 is a perspective view showing a flux melt supply apparatus according to an embodiment of the present invention, Figure 2 is a cross-sectional view showing an outlet nozzle of the melting furnace according to an embodiment of the present invention, Figure 3 is an embodiment of the present invention Figure 4 is a longitudinal cross-sectional view showing the outlet nozzle of the melting furnace, Figure 4a and Figure 4b is an operating state diagram showing the operating state of the flux melt supply apparatus according to an embodiment of the present invention.

First, the mold flux supply apparatus for melting and supplying the mold flux PF supplied to the inside of the mold 10 in the continuous casting process for the purpose of the present invention will be described as an example. However, the flux melt supply device according to the present invention may be applied to a device for melting and supplying various types of flux materials that need to be melted before supplying, rather than being limited to supplying the mold flux.

Flux melt supply apparatus according to an embodiment of the present invention as shown in the figure melts the mold flux (PF), the melting furnace 100 is formed with an outlet 110 on the side; Tilting means (200) for tilting the melting furnace (100); Is equipped with a heating heater 320 is mounted to the outlet 110 of the melting furnace 100, the heating the molten mold flux (LF), the temperature sensor 330 for measuring the temperature of the molten mold flux is provided An outlet nozzle 300; A moving means 400 provided to be movable to install the tilting means 200; One side is installed in the moving means 400 to be positioned below the outlet nozzle 300, the other side includes an injection nozzle 500 extending in the upper direction of the mold (10).

Melting furnace 100 is a means for melting the mold flux (PF) to be injected into the upper surface of the mold 10 from the outside of the mold 10, the inlet for injecting the mold flux (PF) in the upper and opening and closing the inlet Cap 120 is provided, the outlet 110 is formed on one side. In this case, the melting furnace 100 may be a melting furnace of various methods that can melt the mold flux (PF). For example, an electrically heated melting furnace or a gas burner heating melting furnace may be applied. In this embodiment, a gas burner heating melting furnace in which a plurality of gas burners 101 are provided on the side of the melting furnace is adopted.

The tilting means 200 is a means for tilting the melting furnace 100 to discharge the mold flux LF melted in the melting furnace 100 to the injection nozzle 500 (hereinafter, referred to as tilting). A support housing 210 for supporting the melting furnace 100; A tilt shaft 220 installed in the middle lower region of the support housing 210 to support both ends of the support housing 210 in a vertical direction; It is installed on at least one lower area of the support housing 210 includes a tilt driving unit 240 for lifting up and down one side of the support housing 210.

The support housing 210 is a means for fixing the melting furnace 100, and fixes the lower side and the side of the melting furnace 100. Of course, the support housing 210 is not limited to the shape of the present embodiment, and may be variously changed in correspondence to the shape of the melting furnace 100 and the heating method of the melting furnace 100.

The tilting shaft 220 supports the lower region of the support housing 210 to tilt the support housing 210 in one direction to serve as a center of tilting. In this case, the tilt shaft 220 is supported at both ends of the bearing box 230 so as to be freely rotated in the bearing box 230, and a part of the outer circumferential surface of the tilt shaft 220 is fixed to the bottom surface of the support housing 210. do. Accordingly, the support housing 210, that is, the melting furnace 100 is tilted when the tilt shaft 220 is rotated.

The bearing box 230 is installed on the base plate 410 constituting the moving means 400 to be described later or the mounting plate 410a installed on the base plate 410, the upper portion of the base plate 410 The front stopper 413 and the rear stopper 415 are installed in the lower regions of the front and rear of the support housing 210, respectively. At this time, the front is the direction in which the exit nozzle 300 is provided in the drawing, the rear refers to the direction in which the cap 120 is provided.

The front stopper 413 is formed to have a shorter length than the rear stopper 415. For example, the front stopper 413 limits the maximum value of the inclination when the support housing 210, that is, the melting furnace 100 is inclined forward for the discharge of the molten mold flux LF. And the rear stopper 415 limits the maximum slope of the rear of the melting furnace 100 so that the melting furnace 100 can be parallel.

The tilt driving part 240 is installed on an upper portion of the base plate 410 or the mounting plate 410a, and as a means for tilting the melting furnace 100 forward by elevating the rear region of the support housing 210, the support housing 210. It can be implemented in various ways to raise and lower). For example, by adopting the cylinder 241, the rod 243 of the cylinder 241 is connected to the rear lower surface of the support housing 210, and the support housing is operated by an operation of drawing or drawing the rod by operating the cylinder 241 ( 210 can be tilted.

The outlet nozzle 300 is mounted on the outlet 110 of the melting furnace 100 to melt the temperature of the molten mold flux LF and the injection flows (hereinafter, referred to as an injection nozzle 500 through the outlet nozzle 300). Means for controlling the direction of the injected mold flux (LF) as " injection flow ", comprising: a nozzle body 310 formed of refractory material and having a flow path through which both ends communicate; A heating heater 320 embedded in the nozzle body 310 to be adjacent to the flow path 311; The temperature sensor 330 penetrates the nozzle body 310 and is exposed to the flow path 311.

The nozzle body 310 has a pipe shape in which the flow path 311 is formed, and a connection part 313 connected to the melting furnace 100 is formed at one end thereof, and the flow path 311 is formed at the other end of the nozzle body 310. The auxiliary nozzle part 340 is formed to guide the discharge direction of the molten mold flux LF while extending ().

At this time, the flow path 311 is preferably formed to be inclined downward in the other end direction from one end of the nozzle body (310). Thus, the molten mold flux LF discharged through the outlet nozzle 300 is smoothly maintained.

The auxiliary nozzle unit 340 is a means for guiding the injection flow of the molten mold flux LF toward the injection nozzle 500. The auxiliary nozzle unit 340 may be formed of a refractory material and may guide the flow of the molten mold flux LF. It can be implemented in various shapes. For example, the funnel may be cut in half, and the cross section may be implemented in a top open nozzle shape having a “V” or “U” shape.

The heating heater 320 is embedded in the nozzle body 310 to prevent the temperature of the molten mold flux LF discharged through the inside of the outlet nozzle 300 from falling, and is melted in the nozzle body 310. As a means for preventing the mold flux LF from solidifying, a platinum heater is provided in a shape surrounding the outer periphery of the flow path 311. Accordingly, at least a portion of the nozzle body 310 is provided with a lead 321 and a lead terminal 323 for supplying power to the heating heater 320. Of course, the heating heater 320 is not limited to the platinum heater method may be implemented by changing various methods for heating the nozzle body 310.

The temperature sensor 330 is a means for measuring the temperature of the molten mold flux LF discharged through the flow path 311 of the nozzle body 310 in real time, and passes through the nozzle body 310 to be exposed to the flow path. The heat resistant tube mold flux PF and the thermocouple 333 embedded in the heat resistant tube 331 may be implemented. Of course, the temperature sensor 330 is not limited to the exemplary embodiment, but various methods for measuring the temperature of the molten mold flux LF discharged in real time may be applied.

The moving means 400 is a means for moving the apparatus according to the present invention by installing the melting furnace 100 and the tilting means 200, and a base plate 410 on which a plurality of wheels 411 are mounted. It includes. The moving means 400 is not limited to the embodiments shown and may be implemented in various ways. The base plate 410 may be further provided with an installation plate 410a in which the bearing box 230, the front stopper 413, and the rear stopper 415 are installed.

The injection nozzle 500 is a means for supplying the molten mold flux LF melted in the melting furnace 100 through the outlet nozzle 300 to the upper surface of the mold surface of the mold 10. An injection hole 510 into which the molten mold flux LF falling from the nozzle 300 is injected is formed, and the discharge hole 520 from which the molten mold flux LF is discharged to the mold 10 on the other side or the bottom thereof. Is formed. In addition, the injection nozzle 500 is provided with a heat insulating cover 530 for insulating the mold flux (LF) that is melted and transported. At this time, the heat insulating cover 530 may be provided with a heating means 531 for heating the injection nozzle 500.

In order to fix the injection nozzle 500 to the moving means 400, the base plate 410 or the installation plate 410a of the moving means 400 is provided with one side area and an intermediate area of the injection nozzle 500. A supporting frame 420 is provided.

On the other hand, the flux melt supply apparatus according to an embodiment of the present invention is a control unit 600 for controlling the operation of the heating heater 320 in response to the temperature of the molten mold flux (LF) measured by the temperature sensor 330 More). Thus, the molten mold flux LF is controlled by controlling the operation degree of the heating heater 320 according to the temperature of the mold flux LF that is melted measured in real time by the temperature sensor 330 and passes through the outlet nozzle 300. ) Is always discharged at a constant temperature. As the outlet nozzle 300 is heated by the heating heater 320, the molten mold flux LF is prevented from being solidified and attached to the nozzle body 310 of the outlet nozzle 300.

In addition, the controller 600 may further include a display device for displaying the temperature measured by the temperature sensor 330 so that an operator can identify the same.

The operating state of the flux melt supply apparatus according to an embodiment of the present invention configured as described above will be described with reference to the drawings.

As shown in FIG. 4A, the apparatus is moved such that the discharge port 520 of the injection nozzle 500 is disposed on the mold 10 while the cylinder 241 is operated to position the melting furnace 100 in parallel. . Then, the cap 120 of the melting furnace 100 is opened and the mold flux PF in the form of powder or granules is charged into the melting furnace 100, and then the cap 120 is closed to start melting the mold flux PF. In this manner, the mold flux PF is completely melted. At this time, the outlet nozzle 300 is not shown, but is closed by a separate cap or valve.

When the melting of the mold flux PF is completed, the continuous casting process is started, and at the same time, the cylinder 241 is operated to raise the support housing 210, that is, the rear of the melting furnace 100, so that the direction of the outlet nozzle 300 is increased. Tilt the melting furnace 100 to be inclined downward. The molten mold flux LF is injected into the inlet 510 of the injection nozzle 500 through the outlet nozzle 300 by removing the cap closing the outlet nozzle or opening the valve. At this time, the molten mold flux LF is accurately injected into the injection hole 510 of the injection nozzle 500 by receiving the guide of the auxiliary nozzle part 340 formed at the end of the outlet nozzle 300. The molten mold flux LF injected into the injection hole 510 of the injection nozzle 500 is transferred along the injection nozzle 500 and discharged to the upper surface of the mold surface of the mold 10 through the discharge hole 520.

At this time, by measuring the temperature of the molten mold flux (LF) in the temperature sensor 330 installed in the outlet nozzle 300, in response to controlling the operation degree of the heating heater 320 is installed in the outlet nozzle (300) The temperature of the molten mold flux LF can be kept constant at all times, and the outlet nozzle 300 is heated by the heating heater 320 so that the molten mold flux LF is nozzle body 310 of the outlet nozzle 300. ) Is prevented from solidifying and attaching.

The present invention is not limited to the above-described embodiments, but may be embodied in various forms. In other words, the above-described embodiments are provided so that the disclosure of the present invention is complete, and those skilled in the art will fully understand the scope of the invention, and the scope of the present invention should be understood by the appended claims .

10: mold 100: melting furnace
200: tilting means 210: support housing
220: tilting shaft 240: tilting drive unit
300: exit nozzle 310: nozzle body
320: heating heater 330: temperature sensor
340: auxiliary nozzle unit 400: moving means
500: injection nozzle 600: control unit

Claims (11)

delete delete delete An apparatus for melting the flux injected into the mold,
A melting furnace for melting the flux and having an outlet at a side thereof;
An outlet nozzle mounted to an outlet of the melting furnace, provided with a heating heater for heating the melted flux, and having a temperature sensor for measuring the temperature of the melted flux;
An injection nozzle having one side installed at a lower portion of the outlet nozzle and the other side extending in an upper direction of the mold to supply the melted flux to the mold;
A tilting means having a support housing for supporting the melting furnace, the tilting means for tilting the melting furnace;
The melting furnace, the tilting means and the injection nozzle is installed, comprising a moving means for moving the melting furnace, the tilting means and the injection nozzle,
Wherein,
A base plate on which a plurality of wheels are mounted;
At least one support frame installed on the base plate to support the injection nozzle to fix the injection nozzle;
A front stopper and a rear stopper recessed in lower regions of the front and rear of the support housing at an upper portion of the base plate;
Lt; / RTI >
The outlet nozzle,
A flow passage through which both ends communicate with each other, the nozzle body having one end connected to the melting furnace;
And an auxiliary nozzle portion formed of a refractory body, having an open top portion, connected to the other end of the nozzle body to extend a flow path, and guiding the discharge direction of the melted flux toward the injection nozzle. The method of claim 4,
The auxiliary nozzle portion is a flux melt supply device having a cross-sectional shape of the upper open nozzle having a "V" or "U" shape. The method of claim 4,
And a control unit for controlling the operation of the heating heater in response to the temperature of the melted flux measured by the temperature sensor. The method of claim 4,
The injection nozzle is a flux melt supply apparatus is formed in the injection hole is injected into the molten flux falling from the outlet nozzle in the upper portion of the one side, the discharge port for discharging the molten flux in the mold on the other side or the lower portion. The method of claim 4,
Flux supply device is installed in the injection nozzle is a heat insulating cover for insulating the melted flux. delete The method of claim 4, wherein the tilting means
A tilt shaft installed at an intermediate lower region of the support housing to support both ends of the support housing in a vertical direction;
And a tilt driving part installed at at least one lower region of the support housing to move one side of the support housing upward and downward.
delete

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