KR20030005482A - Electric furnace for manufacturing glass and method for manufacturing glass using the electric furmace - Google Patents

Abstract

PURPOSE: An electric melting furnace for manufacturing high quality glass is provided, which is characterized in that a dam between melting pot and purifying pot is set to have space for storing glass melt and keeping temperature of glass melt constant. CONSTITUTION: The glass manufacture method using electric melting furnace comprises the steps of: feeding glass materials into a melting pot(110); melting glass materials by heating a first electrode rod(220) set in the melting pot; flowing completely melted glass among molten glass into a purifying pot(130) over a dam(200) set on the end of a passage between melting pot and purifying pot, the entrance of the purifying pot; keeping the temperature of glass melt high by heating a second electrode rod(230) set in the purifying pot; carrying the glass melt to the working area. In case of non-working time, the power is supplied to only the second electrode rod and the flow of glass melt between melting pot and purifying pot is blocked, which results in that the temperature of molten glass in a storing space(140) of the purifying pot is high enough to manufacture high quality glass.

Description

ELECTRIC FURNACE FOR MANUFACTURING GLASS AND METHOD FOR MANUFACTURING GLASS USING THE ELECTRIC FURMACE

The present invention relates to an electric melting furnace for glass manufacturing and a glass manufacturing method using the electric melting furnace for glass manufacturing, and more particularly, by installing a dam having a predetermined height between a melting chamber and a clarification chamber for melting a raw material of glass. The glass is formed at the bottom of the clarification chamber, and the glass raw material and the glass raw material stored in the storage are melted by electricity, so that the glass quality can be improved and the economic effect of energy saving can be achieved. An electric melting furnace for manufacturing and the glass manufacturing method using this electric melting furnace for manufacturing glass.

In general, glass melts the glass raw material at a high temperature, and then transfers the glass to a clean zone to produce glass of good quality.

1 is a schematic view showing a conventional conventional glass melting furnace 10, as shown in the melting chamber 20, the glass raw material is injected and melted, and the glass raw material melted in the melting chamber 20 Is fed to the clarification chamber 40 and the combustion chambers 28 and 42 formed on the upper side of the fusion chamber 20 and the clarification chamber 40 to be transferred back to the work tool for glass production. 20) and the refractory 50 is made to wrap and keep warm.

Therefore, when the raw material of glass is thrown into the said melting chamber 20, the upper side forms the raw material layer 22 by the operation of the combustion chamber 28 formed in the upper side of this melting chamber 20, and gradually melts, After forming the molten layer 24, the fully molten fully molten layer 26 sinks to the bottom.

Only the completely molten glass raw material in the molten glass raw material is moved to the clarification chamber 40 through the passage 30 connected to the melting chamber 20 and the bottom of the clarification chamber 40.

The passage 30 connecting the melting chamber 20 and the clarification chamber 40 is formed horizontally at the bottom of the melting chamber 20 and is bent upwardly, whereby the clarification chamber 40 is a melting chamber. It is formed at a position higher than 20.

The upper side of the clarification chamber 40 is also formed in the combustion chamber 42, the high quality molten glass raw material transferred to the clarification chamber 40 is guided to the work tool while maintaining a high temperature in a clean state to a high quality glass To be manufactured.

However, each combustion chamber formed on the upper side of the melting chamber and the clarification chamber is difficult to restart when the operation is stopped, so that the combustion chamber must be operated while continuously burning the fuel. Continuous combustion chamber operation as described above not only causes economic losses due to energy waste, but also has a problem of providing a source of environmental pollution due to the outflow of waste gas caused by continuous combustion of fuel.

In addition, the bar is installed in the combustion chamber on the upper side of the melting chamber, there is a problem that the raw material layer and the molten layer and the complete molten layer is not clearly distinguished from the top, the raw material that is not completely melted is transferred to the clarification chamber to produce defective glass. .

Accordingly, the present invention has been made to solve the above problems, a dam is formed in the bottom of the clarification chamber by installing a dam (Dam) having a predetermined height between the melting chamber and the clarification chamber for melting the raw material of the glass By melting the raw materials of the glass and the glass raw materials stored in the storage by electricity, to improve the glass quality and to achieve an economic effect according to the energy saving and the electric melting furnace for glass manufacturing and Its purpose is to provide a glass manufacturing method using a melting furnace.

1 is a schematic configuration diagram of a conventional melting furnace for producing conventional glass.

2 is a schematic configuration diagram of an electric melting furnace for manufacturing glass according to the present invention.

<Description of the symbols for the main parts of the drawings>

100: electric melting furnace for glass production 110: melting chamber

120: passage 130: clarification room

140: Storage 200: Dam

210: power supply device 220: first electrode

230: second electrode

In the electric melting for glass manufacturing of the present invention for achieving the above object, a dam of a certain height is provided at the end side of the passage connecting the melting chamber and the clarification chamber, that is, the inlet end side of the clarification chamber, Forming a reservoir up to the height of the dam;

The first and second electrode rods, each of which is supplied with power from a power supply device, are installed in both sides of the storage chamber of the melting chamber and the clarification chamber.

On the other hand, in the glass manufacturing method using the electric melting furnace for glass manufacturing, by supplying the glass raw material to the melting chamber to operate the power supply device, the heating of the first electrode rods in the melting chamber so as to energize the power supply device The molten glass material, and only the completely molten glass material in the molten glass material is transferred to the clarification chamber through the dam through the passage, and then the second electrode rod built in the clarification chamber is energized with the power supply device. Maintaining the molten high temperature state by heating, and transferring the glass raw material maintaining the molten state in the clarification chamber to a work tool to produce glass;

If it is not during working time, the molten glass raw material stored in the storage room of the clarification chamber by the dam is cut off by turning off the power supply from the power supply to the first electrode and energizing only the second electrode. By maintaining, by transferring to the work tool immediately at the required working time to produce a high quality glass; characterized in that it comprises a.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a schematic configuration diagram of an electric melting furnace for manufacturing glass according to the present invention.

As shown, the electric melting furnace 100 for manufacturing glass according to the present invention, the melting of the glass raw material is injected into the melting chamber 110, and the glass raw material melted in the melting chamber 110 is transported for the glass manufacturing In the refrigerating chamber 130 and the refractory 150 to wrap and keep the melting chamber 110 and the clarification chamber 130 to be transferred to the work tool, the melting chamber 110 and the clarification chamber ( A dam 200 having a predetermined height is provided at an end side of the passage 120 connecting the 130, that is, at the inlet end side of the clarification chamber 130.

Accordingly, the clarification chamber 130 forms a reservoir 140 from the bottom to the height of the dam 200 by the dam 200.

On the other hand, in the storage 140 of the melting chamber 110 and the clarification chamber 130, the first electrode 220 and the second electrode 230 to which the power is supplied from the power supply device 210 are installed on both sides, respectively. have.

Therefore, when the power supply device 210 is operated while injecting the glass material into the melting chamber 110, the glass material is melted by the first electrode rod 220 that is energized with the power supply device 210, and thus the passage of the bottom part. It is transferred to the clarification room 130 through.

At this time, the melting chamber 110, the upper side forms the raw material layer 112, the first electrode 220 around the periphery of the melting layer 114, the completely melted completely melt layer 116 sinks down Through the passage 120, the dam 200 is moved to the clarification chamber 130.

That is, since the first electrode rod 220 is installed at an intermediate position, only the completely molten glass raw material is settled down by forming the peripheral soluble layer 114 and completely melted in the clarification chamber 130. Only the glass raw material is transferred, and the upper side is covered with the raw material layer 112, thereby minimizing the amount of heat emitted, thereby reducing the energy efficiency of the thermal efficiency.

In addition, the second electrode rod 230 that is energized from the power supply device 210 is also installed in the clarification chamber 130, and the molten glass material in the clarification chamber 130 is also added to the second electrode rod 230. By maintaining the molten high temperature state, in this state is transferred to the working tool is made of glass.

On the other hand, in the non-working time, not the working time, the power supply from the power supply device 210 to the first electrode 220 is cut off the power supply to only the second electrode 230 to maintain the working temperature, this In this case, the molten glass raw material in the clarification chamber 130 is bar bar movement to the melting chamber 110 through the passage 120 by the dam 200, and remains in the storage 140 in a clean state, and In the same state, the glass may be produced immediately at the next working time.

As described above, according to the glass manufacturing electric melting furnace of the present invention and the glass manufacturing method using the glass melting electric melting furnace, a melting chamber for injecting and melting a glass raw material and a glass raw material completely melted in the melting chamber are transported and operated. Instead of the combustion chamber, which must be operated continuously in the clarification chamber to be re-transmitted to the sphere, a power supply means is provided to operate only during working hours to melt the raw material or maintain the molten state, thereby reducing the economic loss due to energy waste and reducing the overall cost. Cost) is down, and there is an effect that the problem of environmental pollution due to the outflow of waste gas.

On the other hand, since a dam of a certain height is installed at the end side of the passage connecting the melting chamber and the clarification chamber, that is, at the inlet end side of the clarification chamber, clean glass raw materials are stored at the working temperature at all times, so that high quality immediately There is a useful effect of being able to manufacture the glass.

Although the invention has been described in detail only with respect to the specific examples described, it will be apparent to those skilled in the art that various modifications and variations are possible within the spirit of the invention, and such modifications and variations belong to the appended claims.

Claims (2)

A melting chamber in which the glass raw material is injected and melted, a clarification chamber for transferring the molten glass raw material from the melting chamber to a work tool for manufacturing glass, and a upper side of the melting chamber and the clarification chamber for melting or melting the glass raw material. In the glass melting furnace comprising each combustion chamber to maintain the state and the refractory to surround the melting chamber and the clarification chamber to keep warm, A dam 200 having a predetermined height is provided at an end side of the passage 120 connecting the melting chamber 110 and the clarification chamber 130, that is, the clarification chamber ( 130 constitutes a reservoir 140 from the bottom to the height of the dam 200; In the storage 140 of the melting chamber 110 and the clarification chamber 130, the first electrode 220 and the second electrode 230 which are supplied with power from the power supply device 210 are internally formed at both sides. Furnace for melting glass, characterized in that. After the glass raw material is put into the melting chamber and melted by the operation of the combustion chamber installed on the upper side of the melting chamber, only the completely molten glass raw material in the molten glass raw material is transferred to the clarification chamber through the passage, In the method of manufacturing a glass by maintaining the molten high temperature state by the operation of the combustion chamber installed on the upper side of the clarification chamber, the glass raw material to maintain the molten state in the clarification chamber to the work tool, By inserting the glass raw material into the melting chamber 110 to operate the power supply device 210, by heating of the first electrode rod 220 in the melting chamber 110 to be energized with the power supply device (210). After the molten glass raw material is completely melted in the glass raw material so that it is transferred to the clarification chamber 130 by the dam 200 through the passage 120, and also the power supply device 210 and It maintains the molten high temperature state by heating of the second electrode rod 230 in the clarification chamber 130 so that the electricity is supplied, and re-transfers the glass raw material maintaining the molten state in the clarification chamber 130 to the work tool To produce a glass; When not in working time, the power supply device 210 cuts off the power supply to the first electrode 220, the power supply only to the second electrode 230 to the clarification chamber 130 by the dam 200 The molten glass raw material stored in the storage 140 to maintain the working temperature at all times, to immediately transfer to the working tool at the required working time to produce a high quality glass; Glass manufacturing method using electric melting furnace.