KR20160051200A - Apparatus for making glass - Google Patents

Abstract

The present invention relates to a glass manufacturing apparatus which can manufacture glass by melting a glass material. The glass manufacturing apparatus includes: a high temperature unit used in any one process of a glass manufacturing process; a low temperature unit used in another process of the glass manufacturing process and having a temperature lower than that of the high temperature unit; and an interruption unit having a body in which a condensation space is formed and at least one guide hole formed in the body to be communicated with the condensation space so as to guide a volatile gas emitted from the high temperature unit to a condensation space, and installed between the high temperature unit and the low temperature unit. According to the present invention, since a volatile gas released from a furnace having a relatively high temperature flows towards an agitator having a relatively low temperature, the quality degradation of glass due to a condensed material of the volatile gas can be minimized.

Description

[0001] APPARATUS FOR MAKING GLASS [0002]

The present invention relates to a glass manufacturing apparatus capable of producing glass by melting glass raw materials.

Glass is manufactured in various forms, of which the typical form is flat glass. Many types of flat glass are used in various fields such as a window glass, a window of a vehicle, a screen, a mirror, and the like, and such a flat glass can be manufactured in various ways.

1 is a flow chart schematically showing a manufacturing process using a conventional glass manufacturing apparatus.

Referring to Fig. 1, the glass can be produced through a melting step, a stirring step, a molding step and a slow cooling step.

The melting step may be performed in the melting unit 110 as a step of melting glass raw material (A) to melt glass (C). The stirring step may be performed in the stirring unit 120 as a step of stirring to homogenize the molten glass (C) formed in the melting step. The molten glass (C) which has been stirred is molded through a molding method such as a float method and then slowly cooled.

In the glass manufacturing process comprising such manufacturing processes, Sn, As, Sb oxides and the like, which are used as a refining agent of glass, and B, Na, Ca oxides and the like of glass components may be volatilized. When the volatile gas G flows into the low-temperature region, it is condensed and becomes a crystal or solid state. When the condensate of the volatile gas G falls on the molten glass C having a relatively high temperature, However, if the molten glass C falls into the relatively low-temperature molten glass (C), the molten glass is not melted and causes defective products.

2 is a conceptual diagram of a melting unit and a stirring unit of a conventional glass manufacturing apparatus.

The melting unit 110 includes a melting furnace 112 in which the glass raw material A supplied from the raw material supply unit 130 is accommodated and a combustion unit 112 for supplying heat generated by combustion of a fuel such as natural gas to the melting furnace 112 A heating unit 114, and a power source heating unit 116 that supplies power, which is an electrical energy, to the melting furnace 112.

The stirring unit 120 is provided with a stirring tank 121 in which the molten glass C discharged from the melting unit 110 is accommodated through the connecting pipe 118 and a molten glass C accommodated in the stirring tank 121 are stirred (Not shown). The stirring tank 121 is provided with an upper cover 123 coupled to the opened upper surface of the stirring tank 121, a cover hole 124 formed through the upper cover 123, and a molten glass accommodated in the stirring tank C And a discharge port 128 for discharge. The stirrer 122 is provided so as to penetrate through the cover hole 124 of the upper cover 123 and has one end that is immersed in the molten glass C and another end that extends to the outside of the stirring tank 121, A shaft 125 rotated by a shaft 128 and a plurality of blades 126 coupled to the shaft 125 to be immersed in the molten glass C. [

Since the stirring process using the stirring unit 120 has the relatively low temperature of the molten glass C as compared with other processes, for example, the melting process using the melting unit 110, Product defects due to condensation occur frequently in the agitation process.

Here, the cover hole 124 of the upper cover 123 has a diameter larger than the diameter of the shaft 125 so that the shaft 125 can rotate smoothly, and the shaft 125, which penetrates the cover hole 124, A predetermined gap is formed between the outer peripheral surface of the cover hole 124 and the inner peripheral surface of the cover hole 124. The other end of the shaft 125 is positioned at a lower temperature than the one end of the shaft 125 because the other end of the shaft 125 is immersed in the molten glass C and the other end is located in the outer space of the stirring tank 121 The cover hole 124 of the upper cover 123 is in contact with the outer space of the stirring tank 121 and thus has a lower temperature than the inner space of the stirring tank 121. [

2, the volatile gas G emitted from the melting unit 110 flows toward the stirring unit 120 and flows into the stirring unit 120, more specifically, the other end of the shaft 125, The volatile gas G is supplied to the outer peripheral surface of the other end of the shaft 125 or the inner peripheral surface of the cover hole 124 due to the low temperature of the other end of the shaft 125 or the low temperature of the cover hole 124 A condensate in which the volatile gas G condenses may occur.

This condensate is separated from the other end of the shaft 125 or the cover hole 124 by the vibration of the shaft 125 or the air stream of the volatile gas G and then flows through the cover hole 124 into the stirring tank 121 Falls into the accommodated molten glass (C) and causes a defect in the manufactured product using such molten glass (C). Therefore, the conventional glass manufacturing apparatus 100 has a problem that the quality of the product is deteriorated due to condensate.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a glass manufacturing apparatus improved in structure to prevent volatile gas generated in a high temperature region from flowing into a low temperature region and being condensed.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a glass manufacturing apparatus for producing glass by melting a glass raw material, comprising: a high temperature unit used in any one step of a glass manufacturing process; A low temperature unit used in another process of the glass manufacturing process and having a relatively lower temperature than the high temperature unit; And at least one guide hole formed in the main body so as to communicate with the condensing space, the at least one guide hole guiding the volatile gas discharged from the high-temperature unit into the condensing space, And a shielding unit for shielding the light emitting diode.

Preferably, the high temperature unit is a melting unit for melting the glass raw material.

Preferably, the low-temperature unit is a stirring unit that receives molten glass from the molten unit and stirs the molten glass.

Preferably, the stirring unit comprises: a stirring tank in which molten glass is accommodated; An upper cover having a cover hole, the upper cover being coupled to the opening of the stirring tank; And a stirrer for stirring the glass contained in the stirring tank, the stirrer including a shaft having one end penetrating the cover hole and immersed in the molten glass, and the other end extending to the outside of the stirring tank; The blocking unit is provided so as to surround at least a part of the other end of the shaft extending to the outside of the stirring tank.

Preferably, the blocking unit further comprises a bypass pipe for guiding the volatile gas accommodated in the condensing space to the outside.

Preferably, the shielding unit further comprises a pump installed in the bypass pipe and pumping the volatile gas accommodated in the accommodation space toward the bypass pipe.

Preferably, the shutoff unit further comprises a housing member provided on the bottom surface of the condensation space, the condensation member being formed by condensing the volatile gas in the condensation space.

Preferably, the volatile gas is generated by volatilization of at least one of the oxides contained in the molten glass, the refining agent contained in the molten glass, and the constituents of the container in which the molten glass is contained.

The glass manufacturing apparatus according to the present invention can prevent the volatile gas discharged from the melting furnace having a relatively high temperature from flowing into the stirring tank having a relatively low temperature to be condensed so that the quality of the glass due to the condensation of the volatile gas Can be minimized.

1 is a flow chart schematically showing a manufacturing process using a conventional glass manufacturing apparatus.
2 is a view showing a melting unit and a stirring unit of a conventional glass manufacturing apparatus.
3 is a view of a glass manufacturing apparatus according to a preferred embodiment of the present invention.
Fig. 4 is a view showing an aspect in which the blocking unit of Fig. 3 blocks volatile gas. Fig.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and the inventor may appropriately define the concept of the term in order to best describe its invention It should be construed as meaning and concept consistent with the technical idea of the present invention. Therefore, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

In the drawings, the size of each element or a specific part constituting the element is exaggerated, omitted or schematically shown for convenience and clarity of description. Therefore, the size of each component does not entirely reflect the actual size. In the following description, it is to be understood that the detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

3 is a view showing a glass manufacturing apparatus according to a preferred embodiment of the present invention.

3, a glass manufacturing apparatus 1 according to a preferred embodiment of the present invention is a glass manufacturing apparatus 1 for manufacturing glass by melting a glass raw material R. In the glass manufacturing apparatus 1, Temperature unit used in another process of providing glass, a low-temperature unit having a relatively lower temperature than the high-temperature unit, and a low-temperature unit used to block the movement of the volatile gas (G) Unit 30 as shown in FIG.

The glass manufacturing apparatus 1 according to the preferred embodiment of the present invention includes a plurality of units each used in one of the glass manufacturing processes, wherein a temperature difference according to a process to be performed is formed between the respective units. Therefore, a glass manufacturing apparatus 1 according to a preferred embodiment of the present invention is provided with a high-temperature unit having a relatively high temperature, for example, a melting unit 10 in which a glass melting process is performed, and a low- For example, a stirring unit 20 in which a glass stirring process is performed. Hereinafter, the present invention will be described by taking the case where the high temperature unit is the melting unit 10 and the low temperature unit is the stirring unit 20, for example. However, it should be noted that the present invention is not limited thereto and that the present invention can be applied to other units of the glass manufacturing apparatus 1 as well.

The melting unit 10 is for performing a glass melting process for melting the glass raw material R supplied from the raw material supply unit 40. 1, the melting unit 10 includes a melting furnace 12 in which a glass raw material R supplied from a raw material supply unit 40 is accommodated, a glass raw material R A power heating unit 16 for supplying the glass raw material R with heat generated by a power source which is an electrical energy and a molten glass produced by melting the glass raw material R C) to the stirring unit 20, as shown in Fig.

The melting furnace 12 is formed of a refractory material in which a melting space is formed. The melting space accommodates the glass raw material R discharged from the raw material supply unit 40.

The combustion heating section 14 receives the combustible fuel such as natural gas and supplies heat to the melting furnace 12 by burning the supplied fuel to generate heat. The combustion heating section 14 supplies heat in the direction of the glass raw materials R to the molten glass C at the upper portion of the melting furnace 12 so that the glass raw materials R contained in the melting space can be melted. The combustion heating section 14 may include a plurality of burners located in the ceiling of the melting furnace 12 to supply heat to the upper portion of the melting furnace 12. [

The power supply heating unit 16 supplies power to the melting furnace 12 by receiving a power source as electrical energy. In particular, the power heating section 16 can supply heat inside the molten glass (C) accommodated in the melting space.

As the combustion heating section 14 and the power heating section 16 are provided as described above, the combustion heating section 14 supplies heat from the upper portion of the melting furnace 12 and the power heating section 16 is heated by the molten glass C, the glass raw material R can be melted more effectively. In addition, more uniform control of the molten glass (C) can be enabled by the power heating section (16).

Next, the stirring unit 20 is for performing a glass stirring process for stirring the molten glass (C) transferred from the molten unit (10). 1, the stirring unit 20 includes a stirring tank 21 in which the molten glass C received from the molten unit 10 is received through the connecting pipe 18, An upper cover 23 coupled to the opening and having a cover hole 24 and an agitator 22 for agitating the molten glass C accommodated in the agitating tank 21.

The stirring tank 21 is formed of a refractory material, and a stirring space in which the molten glass C can be received is formed therein. The stirring tank 21 includes an outlet 28 for discharging the molten glass C accommodated in the stirring space. The stirring tank 21 preferably has a cylindrical shape with an open top surface, but is not limited thereto.

The upper cover 23 is formed of a refractory material and is joined to an open top surface of the stirring tank 21 to shield the upper surface of the stirring tank 21. The upper cover 23 also includes a cover hole 24 through which the shaft 25 of the stirring unit 20, which will be described later, can pass. The cover hole 24 has a diameter larger than the diameter of the shaft 25 so that the shaft 25 can rotate smoothly.

The stirring unit (20) stirs the molten glass (C) contained in the stirring space of the stirring tank (21). To this end, the stirring unit 20 includes a shaft 25 which is axially coupled to the drive 27, and a blade 26 which is coupled to the shaft 25. [

The shaft 25 includes a lower end which penetrates the cover hole 24 and is immersed in the molten glass C accommodated in the stirring space of the stirring tank 21 and an upper end extending to the outside of the stirring tank 21. A plurality of blades 26 are coupled to the outer circumferential surface of the shaft 25 at predetermined intervals so as to be immersed in the glass for glass. When the driving device 27 is driven, the shaft 25 and the blade 26 are rotated about the rotation axis of the shaft 25, whereby the blade 26 can stir the molten glass C.

Fig. 4 is a view showing an aspect in which the blocking unit of Fig. 3 blocks volatile gases. Fig.

As, Sb and the like, which are glass fining agents, and B, Na, and Ca oxides, which are components of glass, and the like, in the interior of the melting furnace 12 and the stirring tank 21, Volatile gas G plated on the sidewall of the substrate 21 is generated. When condensate A condensed with volatile gas G (hereinafter referred to as condensate A) falls into molten glass C in a high temperature state, there is no great problem that condensate A is dissolved , When the condensate (A) falls on the molten glass (C) in a low temperature state, it is not melted and adversely affects the yield of the product.

The molten glass (C) contained in the melting furnace (12) has a high temperature due to the heat applied from the combustion heating section (14) and the power heating section (16). Therefore, even if the condensate A falls into the molten glass C contained in the melting furnace 12, the condensate A is melted and there is no great problem. The molten glass C accommodated in the stirring tank 21 has a lower temperature than the molten glass C contained in the molten furnace 12 because no separate heat source is provided in the stirring tank 21. [ Therefore, when the condensate A falls into the molten glass C contained in the stirring tank 21, the condensate A is not dissolved and adversely affects the yield of the product.

As described above, the shaft 25 is installed so as to extend through the cover hole 24 of the upper cover 23 to the outside of the stirring tank 21, and the cover hole 24 is formed by the shaft 25 And has a larger diameter than the shaft 25 so as to be smoothly rotated. Therefore, in the upper end of the shaft 25 directly contacting the upper space of the stirring tank 21 and the cover hole 24, a low temperature region having a temperature lower than the melting space of the stirring tank 21 is formed. When the volatile gas G emitted from the melting furnace 12 comes into contact with the upper end of the shaft 25 or the cover hole 24, the volatile gas G is suddenly cooled by the upper end of the shaft 25 or the cover hole 24, The cooled volatile gas G is condensed to form a condensate A in which the volatilized gas G is condensed on the outer peripheral surface of the upper end of the shaft 25 or the inner peripheral surface of the cover hole 24.

The condensate A is discharged from the agitation tank 21 through the cover hole 24 and the volatile gas G discharged from the melting furnace 12 through the cover hole 24, So as to be separated from the shaft 25 and the cover hole 24. [ The condensate A separated from the shaft 25 and the cover hole 24 is dropped to the molten glass C contained in the stirring tank 21 through the cover hole 24, Resulting in defective products.

In order to solve the above problem, a glass manufacturing apparatus according to a preferred embodiment of the present invention is a glass manufacturing apparatus according to a preferred embodiment of the present invention, in which a volatile gas flowing from the melting furnace 12 to the stirring tank 21, (30) for blocking the airflow of the air bag (G).

The blocking unit 30 is disposed between the molten unit 10 and the stirring unit 20 and more specifically between the upper space of the melting furnace 12 and the upper space of the stirring tank 21 as shown in Fig. . 4, the shutoff unit 30 includes a main body 31 having a condensation space 32 formed therein, a main body 31 formed in the main body 31 to communicate with the condensation space 32, A plurality of guide holes 33 for guiding the released volatile gas G to the condensation space 32, a bypass tube 35 for guiding the volatile gas G contained in the volatile gas G to the outside, And a pump 36 installed in the pipe 35 for pumping the volatile gas G contained in the condensing space 32 toward the bypass pipe 35.

4, the main body 31 has a blocking wall shape capable of blocking the flow of the volatile gas G, and a condensing space 32 in which volatile gas G can be condensed is formed therein do. The main body 31 is installed at a distance from the melting furnace 12 and the stirring tank 21 and is not connected to the heat source and therefore has a lower temperature than the melting furnace 12 or the stirring tank 21. The volatile gas G flowing into the condensing space 32 of the main body 31 is cooled and the condensed product A is formed while the cooled volatile gas G is condensed.

The main body 31 may be formed of a refractory material or formed of platinum or may be formed by coating platinum on the outer circumferential surface of the refractory material. The main body 31 may include a receiving member 34 which is provided on the bottom surface of the condensing space 32 and accommodates the condensate formed by condensing the volatile gas G contained in the condensing space 32.

4, the guide hole 33 is formed through the side wall of the main body 31 and communicates with the outer space of the main body 31 by communicating the condensed space 32 with the outer space of the main body 31, And guides the gas G to the condensation space 32. [ The guide hole 33 is preferably formed along the periphery of the upper portion of the main body 31, but is not limited thereto.

The bypass pipe 35 is provided at the upper end of the main body 31 and extends to the outside of the glass manufacturing apparatus 1 according to the preferred embodiment of the present invention as shown in Fig. The volatile gas G contained in the gas can be discharged.

The pump 36 is installed in the bypass pipe 35 and purges the volatile gas G contained in the condensation space 32 toward the bypass pipe 35 as shown in Fig. When the volatile gas G contained in the condensing space 32 is discharged by the bypass pipe 35 and the pump 36, the condensing space 32 is decompressed and the volatile gas G passing through the main body 31 Can be introduced into the condensation space 32 more effectively.

Hereinafter, the manner in which the flow of the volatile gas G emitted from the melting furnace 12 or the stirring tank 21 is blocked by the interruption unit 30 will be described with reference to the drawings.

3, the oxide contained in the molten glass (C), the refining agent contained in the molten glass (C), and the components of the molten glass or the stirring tank (21) in which the molten glass (C) The volatile gas G generated by the volatilization of at least one of the volatile gases G is discharged to the upper space of the melting furnace 12 or the upper space of the agitating tank 21.

Next, as shown in FIG. 3, a volatile gas (G) flowing from the upper space of the melting furnace 12 toward the upper space of the stirring tank 21 or flowing from the upper space of the stirring tank 21 toward the upper space of the melting furnace 12 Is formed.

4, volatile gas G passing through the vicinity of the main body 31 of the shut-off unit 30 flows into the condensing space 32 through the guide hole 33. Then, as shown in Fig.

4, some of the volatile gas G flowing into the condensing space 32 becomes a condensate A while being cooled by the low temperature into the condensing space 32, and the condensed space 32 Is discharged to the outside by the bypass pipe 35 and the pump 36. As shown in Fig. The condensate (A) formed in the condensation space (32) is accommodated in the accommodation member (34) provided on the bottom surface of the condensation space (32).

As described above, in the glass manufacturing apparatus 1 according to the preferred embodiment of the present invention, the flow of the volatile gas (G) is blocked by the shielding unit (30). Therefore, the volatile gas G emitted from the melting furnace 12 having a relatively high temperature can be prevented from flowing into the stirring tank 21 having a relatively low temperature and being condensed, so that the condensate of the volatile gas G A) can be minimized.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not to be limited to the details thereof and that various changes and modifications will be apparent to those skilled in the art. And various modifications and variations are possible within the scope of the appended claims.

1: Glass making apparatus 10: Melting unit
12: Melting furnace 14: Combustion heating section
16: power heating section 18: connection pipe
20: Stirring unit 21: Stirring tank
22: stirrer 23: upper cover
24: cover hole 25: shaft
26: blade 27: drive device
28: Exhaust port 30:
31: main body 32: condensation space
33: guide hole 34: housing member
35: bypass pipe 36: pump
40: raw material supply unit G: volatile gas
A: Condensate R: Glass raw material
C: molten glass

Claims (8)

A glass manufacturing apparatus for producing a glass by melting a glass raw material,
A high temperature unit used in any one of the steps of the glass manufacturing process;
A low temperature unit used in another process of the glass making process and having a relatively lower temperature than the high temperature unit; And
And at least one guide hole formed in the main body so as to communicate with the condensing space, the at least one guide hole guiding the volatile gas discharged from the high-temperature unit to the condensing space, And a shielding unit provided between the low-temperature units. The method according to claim 1,
Wherein the high-temperature unit is a melting unit for melting a glass raw material. 3. The method of claim 2,
Wherein the low-temperature unit is a stirring unit that receives molten glass from the molten unit and stirs the molten glass. The method of claim 3,
The stirring unit includes:
A stirring tank in which the molten glass is accommodated;
An upper cover having a cover hole, the upper cover being coupled to the opening of the stirring tank; And
And a stirrer for stirring the glass contained in the stirring tank, the stirrer including a shaft having one end penetrating the cover hole and being immersed in the molten glass, and the other end extending to the outside of the stirring tank;
Wherein the blocking unit is provided so as to surround at least a part of the other end of the shaft extending to the outside of the stirring tank. The method according to claim 1,
Wherein the shutoff unit further comprises a bypass pipe for guiding the volatile gas accommodated in the condensing space to the outside. 6. The method of claim 5,
Wherein the blocking unit further comprises a pump installed in the bypass pipe and pumping the volatile gas accommodated in the condensing space toward the bypass pipe. The method according to claim 1,
Wherein the shielding unit further comprises a housing member which is provided on a bottom surface of the condensing space and in which condensed water formed by condensing the volatile gas in the condensing space is accommodated. The method according to claim 1,
Wherein the volatile gas is generated by volatilization of at least one of an oxide contained in the molten glass, a cleaning agent contained in the molten glass, and a constituent component of the container in which the molten glass is contained.

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