KR101376141B1 - Strip caster of magnesium alloy - Google Patents

Abstract

Provide a strip caster of magnesium alloy. According to the present invention, a melting furnace for melting magnesium ingot; A refining furnace connected by the melting furnace and a transfer tube and for refining the molten metal dissolved in the melting furnace; And a ceramic nozzle connected directly to the refining furnace and receiving the molten metal refined by the refining furnace to supply the upper roll and the lower roll.

Description

Strip caster of magnesium alloy {STRIP CASTER OF MAGNESIUM ALLOY}

The present invention relates to a strip caster of magnesium alloy, and more particularly, a magnesium alloy capable of supplying magnesium molten metal to a rotating upper and lower roll using a ceramic nozzle directly connected to a refining furnace after melting and refining a magnesium ingot. Relates to strip casters.

In general, for thin continuous casting of magnesium alloy, magnesium molten metal is supplied to a horizontal thin continuous casting machine by using a horizontal twin roll strip casting method.

The strip caster of the conventional magnesium alloy is a head box, which is an intermediate medium for receiving and storing molten and refined molten metal melted and refined by the melting and refining furnace, for melting and refining the molten metal. It is supplied with a ceramic nozzle for spraying between the upper and lower rolls, the magnesium molten metal passed through the melting furnace and the refining furnace is supplied to the ceramic nozzle by adjusting the amount of molten metal in the head box.

In addition, the melting furnace, the refining furnace, the head box is provided with a heating device for heating it.

However, in the conventional magnesium alloy strip caster, since the head box is provided as an intermediate medium for controlling the molten metal supply between the refining furnace and the ceramic nozzle, there is a problem that the equipment increases.

In addition, since the melting furnace, the refining furnace, and the head box are separately provided with heating devices, there is a problem in that energy efficiency is lowered.

The present invention is to provide a strip caster of magnesium alloy that can supply the molten metal by omitting the head box as an intermediate medium and directly connecting the ceramic nozzle to the refining furnace.

According to one embodiment of the invention, the melting furnace for melting magnesium ingot;

A refining furnace connected by the melting furnace and a transfer tube and for refining the molten metal dissolved in the melting furnace; And

A strip caster of magnesium alloy is provided that is directly connected to the refining furnace and includes a ceramic nozzle for receiving a molten metal refined by the refining furnace and feeding the upper roll and the lower roll.

The transfer tube may be provided with a molten metal feed pump for supplying the molten metal of the melting furnace to the refinery.

A heating furnace for accommodating the melting furnace and the refining furnace together therein may be provided.

The heating member may be provided with a heating member for heating the inside of the heating furnace.

The melting furnace may be provided with a first thermocouple for measuring the temperature of the molten metal in the melting furnace.

The refining furnace may be provided with a second thermocouple for measuring the temperature of the molten metal in the refining furnace.

The refinery may be provided with a melt level sensor for detecting the level of the molten metal in the refinery.

A supply tube for supplying the molten metal refined by the refinery to the ceramic nozzle is installed between the ceramic nozzle and the refinery, and a supply tube heater for heating the supply tube is installed outside the supply tube. Can be.

The heating furnace may be of a closed chamber structure so as to easily heat the melting furnace and the refining furnace.

According to the present embodiment, by omitting the head box from the conventional magnesium alloy strip caster and directly connecting the ceramic nozzle to the refining furnace to supply molten metal, the installation can be simplified as compared with the conventional magnesium alloy strip caster.

In addition, by allowing the refining furnace and the melting furnace to be heated together, energy efficiency due to heating can be increased.

1 is a schematic diagram of a strip caster of a magnesium alloy 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, which will be readily apparent to those skilled in the art to which the present invention pertains. The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

1 is a schematic diagram of a strip caster of a magnesium alloy according to an embodiment of the present invention.

Referring to FIG. 1, a strip caster of magnesium alloy is a device for supplying molten magnesium to the upper and lower rolls that rotate using a ceramic nozzle.

The strip caster of the magnesium alloy is a melting furnace 110 for melting the magnesium ingot 100;

A refining furnace (120) connected to the melting furnace (110) for refining the molten metal dissolved in the melting furnace (110); And

Directly connected to the refining furnace 120, it may include a ceramic nozzle 200 for receiving the molten metal refined by the refining furnace 120 to supply between the upper roll 300 and the lower roll 310. .

Here, the upper and lower rolls 300 and 310 may be located in front of the ceramic nozzle 200.

The magnesium ingot 100 may be supplied to the melting furnace 110 by a transfer device 102.

The melting furnace 110 and the refining furnace 120 may be connected by a transfer tube 130 for transferring the molten metal.

A molten metal supply pump 140 may be installed in the transfer tube 130 to supply the molten metal of the melting furnace 110 to the refining furnace 120.

The molten metal supply pump 140 may be connected to the control unit 400 so as to control the amount of the molten metal supplied to the refining furnace 120 through the transfer tube 130 and may be controlled by the control unit 400. .

In addition, a heating furnace 150 for accommodating the melting furnace 110 and the refining furnace 120 together may be provided to heat the melting furnace 110 and the refining furnace 120 to a constant temperature. have.

The heating member 150 may be provided with a heating member 160 to heat the inside of the heating furnace 150 to maintain the melting furnace 110 and the refining furnace 120 at a constant temperature.

The heating furnace 150 may have a hermetically sealed chamber structure to easily heat the melting furnace 110 and the refining furnace 120.

The melting furnace 110 may be provided with a first thermocouple 170 for measuring the temperature of the molten metal in the melting furnace 110.

In addition, the refining furnace 120 may be provided with a second thermocouple 180 for measuring the temperature of the molten metal in the refining furnace.

The heating member 160, the first thermocouple 170, and the second thermocouple 180 may be connected to the control unit 400 and controlled by the control unit 400.

In addition, the refinement furnace 120 may be provided with a melt level sensor 190 for detecting the level of the molten metal in the refinery 120.

A nozzle heater 210 for heating the ceramic nozzle 200 may be installed outside the ceramic nozzle 200.

A supply tube 220 may be installed between the ceramic nozzle 200 and the refining furnace 120 to supply the molten metal refined by the refining furnace 120 to the ceramic nozzle 200.

A supply tube heater 230 for heating the supply tube 220 may be installed outside the supply tube 220.

1 and 2, the operation of the strip caster of the magnesium alloy according to an embodiment of the present invention will be described.

First, the magnesium ingot 100 is supplied to the melting furnace 110 by the transfer device 102, and is melted into the molten metal in the melting furnace 110.

The molten metal dissolved in the melting furnace 110 is supplied to the refining furnace 120 through the transfer tube 130 by the driving of the molten metal supply pump 140 and then refined.

The molten metal refined in the refining furnace 120 is supplied to the supply tube 220 and then supplied between the upper roll 300 and the lower roll 310 through the ceramic nozzle 200.

In addition, the heating member 160 to heat the inside of the heating furnace 150 to a constant temperature, the melting furnace 110 and the refining furnace 120 are both located inside the heating furnace 150. Since the melting furnace 110 and the inside of the refining furnace 120 may be maintained at a constant temperature.

The ceramic nozzle 200 may be heated to a constant temperature by the nozzle heater 210, and the supply tube 220 may be heated to a constant temperature by the supply tube heater 230.

At this time, the molten metal level sensor 190 detects a molten metal level in the refinery 120, and the sensed molten metal level value is transmitted to the controller 400, and the controller 400 controls the molten metal level. The amount of molten metal supplied to the ceramic nozzle 200 may be controlled by controlling the amount of molten metal supplied to the refinery 120 by adjusting the driving state of the molten metal supply pump 140 according to a value.

In addition, the first thermocouple 170 measures the temperature of the molten metal in the melting furnace 110, the second thermocouple 180 measures the temperature of the molten metal in the refining furnace 120, the first thermocouple ( 170 and the temperature measurement value of the second thermocouple 180 is transmitted to the control unit 400, the control unit 400 by adjusting the heating degree of the heating member 160 according to the temperature measurement value, The interior of the heating furnace 150, that is, the internal temperature of the melting furnace 110 and the refining furnace 120 may be constantly adjusted.

Therefore, according to the present invention, by omitting the head box in the conventional magnesium alloy strip caster to connect the ceramic nozzle directly to the refining furnace to supply the molten metal, simplifying the installation compared to the conventional magnesium alloy strip caster, energy The efficiency can be increased.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Of course.

100: magnesium ingot 110: melting furnace
120: refining furnace 130: transfer tube
140: molten metal supply pump 150: heating furnace
160: heating member 200: ceramic nozzle
220: supply tube 300: upper roll
310: lower roll

Claims (9)

Melting furnace for melting magnesium ingot;
A refining furnace connected by the melting furnace and a transfer tube and for refining the molten metal dissolved in the melting furnace; And
A ceramic nozzle directly connected to the refining furnace and supplied with the molten metal refined by the refining furnace to supply between the upper roll and the lower roll.
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The transfer tube is provided with a molten metal supply pump for supplying the molten metal of the melting furnace to the refinery,
The refinery is provided with a melt level sensor for detecting the level of the molten metal in the refinery,
The molten metal supply pump and the molten metal level sensor are connected to a controller and controlled by the controller,
The control unit adjusts the amount of melt supplied to the refinery by adjusting the driving state of the melt supply pump according to the melt level value detected by the melt level sensor,
A heating furnace for accommodating the melting furnace and the refining furnace together;
The heating member is provided with a heating member for heating the inside of the heating furnace,
The melting furnace is provided with a first thermocouple for measuring the temperature of the molten metal in the melting furnace,
The refining furnace is provided with a second thermocouple for measuring the temperature of the molten metal in the refining furnace,
The heating member, the first thermocouple and the second thermocouple are connected to the control unit so that the internal temperatures of the melting furnace and the refining furnace can be constantly adjusted according to the temperature measurement values of the first thermocouple and the second thermocouple. Strip caster of magnesium alloy controlled by a control unit. delete delete delete delete delete delete The method of claim 1,
A supply tube is provided between the ceramic nozzle and the refining furnace to supply the molten metal refined by the refining furnace to the ceramic nozzle.
Strip casters of magnesium alloy on the outside of the supply tube is provided with a supply tube heater for heating the supply tube. The method of claim 1,
The heating furnace of the magnesium alloy strip caster having a hermetic chamber structure to easily heat the melting furnace and the refining furnace.

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