KR20120124514A - Treating apparatus for flat glass - Google Patents

Abstract

PURPOSE: A plate glass processing apparatus is provided to prevent spots generated on a plate glass by washing the plate glass using a grinding unit, a washing unit, a rinsing unit, and a drying unit. CONSTITUTION: A transfer unit(120) transfers a plate glass. A washing unit(140) cleans the transferred plate glass. A rinsing unit(150) washes the washed plate glass. A blower(171) of a drying unit(170) generates high pressure air for drying the washed plate glass. An air knife(173) of the drying unit sprays the air supplied by the blower to the surface of the plate glass.

Description

Plate Glass Processing Equipment {TREATING APPARATUS FOR FLAT GLASS}

The present invention relates to a plate glass processing apparatus, and more particularly to a plate glass processing apparatus for polishing and cleaning a large glass plate used in large glass windows, solar panels, and the like.

Generally, flat glass is used in various applications. It can be simply used for large glass windows or alternatively for the surface of large televisions and solar panels.

On the other hand, in the case of such a large plate glass for a long time there is a problem that a minute scratches on the surface, or contaminants are fixed to reduce the inherent permeability. Therefore, there is a need for an apparatus for cleaning or polishing a long time used plate glass.

Conventionally, there was an apparatus for washing and drying large plate glass for construction, but this apparatus is simply to wash the plate glass and absorb and remove the washing water with a sponge, so when cleaning the plate glass, fine scratches or minute stains occur on the plate glass. The back remained.

Briefly explaining such a conventional device by installing a plurality of upper and lower rotary sponge rollers in contact with the upper and lower rotary brush for washing and the upper and lower surfaces of the plate glass, the plate glass is washed while passing through the upper and lower rotary brushes for cleaning. Then, the rotary sponge roller of either the upper or lower portion is pressed against the plate glass more strongly than the other rollers while passing through the upper / lower rotary sponge roller, so that the residual water of the side portion corresponding to the thickness of the plate glass is absorbed and removed. have.

However, since the water droplets are removed by contact with the sponge roller, there is a problem in that fine stains on both sides of the plate glass are not completely removed.

In addition, a problem arises that the plate glass washed by the transfer roller for transferring the plate glass is contaminated again during the transfer of the plate glass.

In addition, in the case of the conventional plate glass processing apparatus is to simply remove the contaminants adhered to the surface of the plate glass, there was a problem that can not remove such as small scratches generated in the plate glass itself.

The present invention has been made in order to solve the above problems, it is an object of the present invention to provide a plate glass processing apparatus that can remove minute scratches and the like damaged on the surface of the plate glass.

In addition, the present invention has been made in order to solve the above problems, it is an object of the present invention to provide a plate glass processing apparatus that can prevent the plate glass from being contaminated again when moving the plate glass for cleaning when cleaning the plate glass. .

In addition, the present invention has been made to solve the above problems, an object of the present invention is to provide a plate glass processing apparatus so that stains are not left by the detergent and water administered to the plate glass for cleaning when the plate glass.

Plate glass processing apparatus according to an embodiment of the present invention for achieving the above object is a conveying unit for supplying and conveying the plate glass, a washing unit for washing the plate glass conveyed by the conveying unit, and the plate glass passed through the washing unit And a drying unit including a rinse unit for cleaning the air, a blower for generating high pressure air to dry the plate glass passing through the rinse unit, and an air knife for injecting air supplied from the blower to the surface of the plate glass. It is preferable.

In this case, the drying unit may include a blower for generating high pressure air, and an air knife for spraying air supplied from the blower to the surface of the plate glass.

In addition, the air knife may include a residence space in which the air supplied from the blower stays, and a rectangular nozzle having a central portion protruding in a direction opposite to the traveling direction of the plate glass.

In addition, the rectangular nozzle is inclined in the traveling direction of the plate glass, it is possible to inject air in a direction opposite to the traveling direction of the plate glass.

In addition, the wash water used in the rinse portion may include a reservoir to precipitate and store the water used in the washing unit.

The washing unit may include an upper surface washing unit for washing the upper surface of the plate glass, and a lower surface washing unit for washing the lower surface of the plate glass.

The rinse portion may include an upper rinse portion for rinsing the upper surface of the plate glass, and a lower rinse portion for rinsing the lower surface of the plate glass.

In addition, the water tank is provided with a plurality of rinse reservoir portion for storing the washing water used in the rinse portion, a plurality of washing reservoir for storing the washing water used in the washing unit, the rinse reservoir and the washing Each partition wall partitioning the reservoir may have a leaking hole that increases in height with respect to the advancing direction of the plate glass.

1 is a side view showing a plate glass processing apparatus according to the present invention.
2 is a plan view showing a plate glass processing apparatus according to the present invention.
3 is a side view showing a polishing part of the plate glass processing apparatus according to the present invention.
4 is a cross-sectional view showing the polishing roller of the plate glass processing apparatus according to the present invention.
Figure 5 is a side view showing the washing portion of the plate glass processing apparatus according to the present invention.
6 is a cross-sectional view showing a washing roller of the plate glass processing apparatus according to the present invention.
Figure 7 is a side view showing a rinse portion of the plate glass processing apparatus according to the present invention.
Figure 8 is a side cross-sectional view showing the reservoir of the plate glass processing apparatus according to the present invention.
9 is a perspective view showing an air knife of the plate glass processing apparatus according to the present invention.
10 is a cross-sectional view showing an air knife of the plate glass processing apparatus according to the present invention.

In describing the present invention, the names of the elements defined are defined in consideration of functions in the present invention. Therefore, it should not be understood as a meaning limiting the technical components of the present invention. In addition, each name defined in each component may be referred to as other names in the art.

Hereinafter, the plate glass processing apparatus 100 according to the embodiment of the present invention will be described in detail.

First, with reference to the accompanying drawings 1 to 2 will be described in detail a plate glass processing apparatus according to an embodiment of the present invention.

1 is a side view showing a plate glass processing apparatus according to the present invention, Figure 2 is a plan view showing a plate glass processing apparatus according to the present invention.

As illustrated, the plate glass processing apparatus 100 according to the present invention forms an outer shape and has a rectangular frame 110 in which various components to be described below are installed, and a movement path of the plate glass G along the longitudinal direction of the frame 110. Forming and conveying plate 120 to move the plate glass (G) is introduced at the same time, the polishing unit 130 for polishing the surface of the plate glass moved by the conveying unit 120 through the cerium, and the polished plate glass (G) The washing unit 140 for cleaning the surface of the rinse, the rinsing unit 150 for treating the detergent remaining on the surface of the plate glass (G), and the washing water remaining on the surface of the rinsed plate glass (G) by drying And a storage unit 160 for storing the drying unit 170 and the washing unit 140 and the rinsing unit 150 so as to sequentially supply the washing water.

Hereinafter, the transfer unit according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is a side view showing a polishing part of the plate glass processing apparatus according to the present invention, Figure 4 is a cross-sectional view showing a polishing roller of the plate glass processing apparatus according to the present invention.

The polishing unit 130 is for polishing the surface of the plate glass (G) conveyed by the transfer unit 120 through the cerium. The polishing unit 130 includes an upper surface polishing portion 133a for polishing the upper surface of the plate glass G and a lower surface polishing portion 133b for polishing the lower surface of the plate glass G. The upper surface polishing unit 133a and the lower surface polishing unit 133b are installed in the installation unit 131 fixed to the frame 110.

On the other hand, the upper portion of the installation portion 131 is provided with a polishing motor 132 for supplying power to the upper surface polishing portion 133a or / and the lower surface polishing portion 133b. The upper polishing portion 133a and / or the lower polishing portion 133b receives the power of the polishing motor 132 from a separate power transmission member 132a.

Here, the upper polishing part 133a is provided on the upper pressing bracket 135a coupled to the mounting part 131 so as to be slidably movable in the vertical direction, and the upper pressing bracket 135a is provided on the mounting part 131 to plate glass G. It is provided with a downward pressing portion 134a for pressing to the side, and a top polishing roller 136a rotatably provided in the lower portion of the upper pressing bracket 135a.

The lower pressing portion 134a and the upper pressing bracket 135a of the upper polishing portion 133a are formed to be opposed to both sides of the moving direction of the plate glass G to support both sides of the upper polishing roller 136a. .

In addition, the lower surface polishing part 133b is provided with a lower surface pressing bracket 135b coupled to the mounting portion 131 so as to be movable in a vertical direction, and the lower surface pressing bracket 135b is provided on the mounting portion 131. An upper pressing part 134b pressurized toward the side and an upper grinding roller 136a rotatably provided at a lower portion of the lower pressing bracket 135b.

The upper pressing portion 134b and the lower pressing bracket 135b of the lower surface polishing portion 133b are provided to face opposite sides of the moving direction of the plate glass G to support both sides of the lower polishing roller 136b. .

Here, the upper polishing roller 136a and the lower polishing roller 136b may include a rotary shaft 137 in which a hollow is formed, a cylindrical urethane foam 139 provided on an outer circumferential surface of the rotary shaft 137, and one end of the rotary shaft 137. It is provided in the inlet 137a and the cerium mixture is supplied to the rotatable shaft 137 is rotatably supported with respect to the inlet 137a and the cerium mixture supplied through the inlet 137a is supplied to the hollow of the rotary shaft 137 The rotary joint 138 is provided. On the other hand, the outer circumferential surface of the rotary shaft 137 is formed with a plurality of through-holes cerium mixture supplied to the injection hole 137a is injected to the outer peripheral surface of the urethane foam 139 through the urethane foam 139 through the rotary shaft 137 .

The upper polishing roller 136a and the lower polishing roller 136b spray the cerium mixture supplied separately. At the same time, the top and bottom surfaces of the plate glass G are polished while being rotated by receiving the power supplied from the polishing motor 132 by the power transmission member 132a. At this time, the upper surface polishing roller 136a and the lower surface polishing roller 136b rotated by the power transmission member 132a are respectively rotated in the opposite direction to the conveying direction of the plate glass G which is moved by the conveying unit 120. Polish both sides of).

Hereinafter, the washing unit 140 will be described in detail with reference to the accompanying drawings.

Figure 5 is a side view showing a washing portion of the plate glass processing apparatus according to the present invention, Figure 6 is a cross-sectional view showing a washing roller of the plate glass processing apparatus according to the present invention.

The washing unit 140 is for washing the surface of the plate glass (G) transported by the transfer unit 120 through the washing water. The washing unit 140 includes an upper washing unit 143a for washing the upper surface of the plate glass G and a lower washing unit 143b for washing the lower surface of the plate glass G. The upper surface washing unit 143a and the lower surface washing unit 143b are installed in the installation unit 141 fixed to the frame 110.

On the other hand, the upper portion of the installation unit 141 is provided with a washing motor 142 for supplying power to the upper surface washing portion 143a or / and the lower surface washing portion (143b). The upper surface washing unit 143a and / or the lower surface washing unit 143b receive the power of the washing motor 142 from a separate power transmission member 142a.

Here, the upper washing unit 143a is provided with an upper pressing bracket 145a coupled to the mounting unit 141 so as to be slidably movable in a vertical direction, and the upper pressing bracket 145a is provided at the mounting unit 141 to form a plate glass G. It is provided with a downward pressing portion 144a for pressing to the side, and an upper surface washing roller 146a rotatably provided at the lower portion of the upper pressing bracket 145a.

The lower pressing part 144a and the upper pressing bracket 145a of the upper washing part 143a are symmetrical to both sides of the moving direction of the plate glass G to support both sides of the upper washing roller 146a. .

Then, the lower surface washing unit 143b is provided with a lower surface pressing bracket 145b which is slidably coupled to the mounting unit 141 in a vertical direction, and the lower surface pressing bracket 145b is provided on the mounting unit 141 to the plate glass G. The upper pressing portion 144b pressurized to the side and the lower surface of the pressing bracket 145b is provided with a top washing roller 146a rotatably provided.

The upper pressing portion 144b and the lower pressing bracket 145b of the lower surface washing portion 143b are provided in symmetrical shapes on both sides of the moving direction of the plate glass G to support both sides of the lower washing roller 146b. .

Here, the upper surface washing roller 146a and the lower surface washing roller 146b may be provided at one end of the rotating shaft 147 on which the hollow is formed, the brush 149 provided on the outer circumferential surface of the rotating shaft 147, and the rotating shaft 147. A rotary joint 148 for rotatably supporting the injection hole 147a and the injection hole 147a and simultaneously supplying the washing water supplied through the injection hole 147a to the hollow of the rotation shaft 147. It is provided. On the other hand, a plurality of through holes are formed on the outer circumferential surface of the rotating shaft 147, and the washing water supplied to the injection hole 147a is supplied through the through holes of the rotating shaft 147 and sprayed onto the surface of the plate glass G by the brush.

Accordingly, the upper surface washing roller 146a and the lower surface washing roller 146b spray washing water supplied separately onto the surface of the plate glass G. At the same time, the power supplied from the washing motor 142 is rotated by receiving power from the power transmission member 142a to wash the upper and lower surfaces of the plate glass G. At this time, the upper surface washing roller 146a and the lower surface washing roller 146b rotated by the power transmission member 142a are respectively rotated in the opposite direction to the conveying direction of the plate glass G which is moved by the conveying unit 120. Clean both sides of).

On the other hand, in the case of the washing unit 140 as described above may be composed of the first, second washing unit (140a, 140b). That is, if necessary according to the washing area of the plate glass (G) it may be configured by a plurality of washing unit 140 to perform the cleaning.

Hereinafter, the rinsing unit 150 will be described in detail with reference to the accompanying drawings.

Figure 7 is a side view showing a rinse portion of the plate glass processing apparatus according to the present invention.

The rinse unit 150 includes an upper rinse unit 151a for spraying the washing water on the upper surface of the plate glass G transferred by the transfer unit 120, and a lower surface rinse unit 151b for spraying the washing water on the lower surface of the plate glass G. ).

Here, the upper rinsing part 151a is installed on the upper frame 110 of the conveying part 120, and the upper rotating nozzle 155a sprays the washing water on the upper surface of the plate glass G in a direction opposite to the conveying direction of the plate glass G. And an upper nozzle bracket 153a rotatably supporting the upper rotating nozzle 155a.

And the lower surface rinsing portion 151b is installed on the lower frame 110 of the conveying unit 120, the lower rotating nozzle 155b for spraying the washing water on the lower surface of the plate glass G in a direction opposite to the conveying direction of the plate glass G. And a lower nozzle bracket 153b for rotatably supporting the lower rotating nozzle 155b.

Here, the upper nozzle bracket 153a and the lower nozzle bracket 153b are formed to face each other in the moving direction of the plate glass G so that both sides of the upper rotating nozzle 155a and the lower rotating nozzle 155b can be rotated, respectively. Support. Accordingly, the upper rotating nozzle 155a and the lower rotating nozzle 155b are rotated between the upper nozzle bracket 153a and the lower nozzle bracket 153b to change the washing water spray angle to the plate glass to spray the washing water.

On the other hand, in the case of the rinse portion 150 as described above may be composed of the first and second rinse portions (150a, 150b). That is, if necessary according to the washing area of the plate glass (G) it may be configured by a plurality of rinse portion 150 to perform the cleaning.

Hereinafter, the reservoir 160 will be described in detail with reference to the accompanying drawings.

Figure 8 is a side cross-sectional view showing the reservoir of the plate glass processing apparatus according to the present invention.

The reservoir 160 is for supplying the washing water to the rinse unit 150 and the washing unit 140 while storing the cerium mixture used in the above-described polishing unit 130. The reservoir 160 is fixed to the frame 110 to be positioned below the polishing unit 130, the washing unit 140, and the rinse unit 150.

Such reservoirs are used in the polishing unit 130, the washing unit 140 and the rinsing unit 150, or a plurality of reservoir tanks so that the washing water supplied to the polishing unit 130, the washing unit 140 and the rinsing unit 150 is stored. It consists of 160 and a plurality of partitions.

Hereinafter, when the washing unit 140 and the rinsing unit 150 of the present invention consists of the first and second washing units 140a and 140b and the first and second rinsing units 150a and 150b, respectively, the structure of the water storage tank 160 will be described. I'll explain. However, the structure of the reservoir 160 is not limited.

Meanwhile, the plate glass G is used in the second rinse part 150b as it passes through the first wash part 140a, the second wash part 140b, the first rinse part 150a, and the second rinse part 150b. The wash water is the least contaminated, the wash water used in the first washing unit 140a is the most contaminated. Therefore, in the present invention, the wash water used in the second rinse unit 150b is used again in the first rinse unit 150a, and the wash water used in the first rinse unit 150a is used again in the second washing unit 140b. Then, the washing water used in the second washing unit 140b is used again in the first washing unit 140a to reuse the washing water. However, the cerium reservoir 169 may be formed independently without being connected to another reservoir.

To this end, the reservoir 160 of the present invention includes a first washing reservoir 165 positioned below the first washing unit 140a, and a second washing reservoir located below the second washing unit 140b. 167, the first rinse reservoir 161 positioned below the first rinse portion 150a, the second rinse reservoir 163 positioned below the second rinse portion 150b, and the polishing portion. The cerium reservoir 169 positioned below the 130 is provided. Meanwhile, in the case of the CE reservoir 169, a drain filter is provided at a lower portion thereof, and the drain filter may prevent drainage of contaminants in the cerium mixture.

Here, a first partition 162 is provided between the second rinse reservoir 163 and the first rinse reservoir 161, and a first barrier 162 is provided between the first rinse reservoir 161 and the second wash reservoir 167. A second partition 164 is provided, a third partition 166 is provided between the second wash reservoir 167 and the first wash reservoir 165, the first wash reservoir 165 and the CE reservoir A fourth partition 168 is provided between the 169.

Here, the first, second, and third partition walls 162, 164, and 166 are formed with first, second, and third leak holes 162a, 164a, and 166a at different heights. Preferably, the first leak hole 162a formed in the first partition 162 is formed at the highest position, the third leak hole 166a is formed at the lowest position, and the second leak hole 164a is formed at the highest position. It is formed between the first leak hole 162a and the third leak hole 166a.

Accordingly, the wash water used in the first and second wash units 140a and 140b and the first and second rinse units 150a and 150b may be disposed in the first and second wash reservoirs 165 and 167 and the first and second wash units. The two rinse reservoirs 161 and 163 are respectively stored.

On the other hand, when the washing water movement process in the reservoir 160, first, the washing water is supplied to the second rinse reservoir (163). Accordingly, the wash water stored in the second rinse reservoir 163 is moved to the first rinse reservoir 161 by the first leak hole 162a formed in the first partition 162 as the amount of the wash water increases. At this time, the washing water is moved to the first rinse reservoir 161 after the precipitation of foreign matter in the second rinse reservoir 163.

In addition, the wash water moved to the first rinse reservoir 161 is used in the first rinse unit 150a and the used wash water is stored in the first rinse reservoir 161. Accordingly, as the amount of washing water is increased in the first rinse reservoir 161, the second rinse reservoir is moved to the second washing reservoir through the second leak hole formed in the second partition wall 164. At this time, the washing water is moved to the second washing reservoir 167 after the precipitation of foreign matter occurs in the first rinse reservoir 161.

Then, the wash water moved to the second wash reservoir 167 is used in the second wash unit 140b and the used wash water is stored in the second wash reservoir 167. Accordingly, as the amount of washing water is increased in the second washing reservoir 167, the washing unit moves to the first washing reservoir through the third leak hole formed in the third partition 166. At this time, the washing water is moved to the first washing water storage unit 165 after the sedimentation of foreign matter occurs in the second washing water storage unit 167.

Finally, the wash water moved to the first wash reservoir 165 is used in the first wash unit 140a, and the used wash water is drained from the first wash reservoir 165.

As described above, the wash water used in the first and second rinse units 150a and 150b and the first and second wash units 140a and 140b may be used again in a previous process according to the degree of contamination. This can significantly reduce the use of wash water.

Hereinafter, the drying unit will be described in detail with reference to the accompanying drawings.

9 is a perspective view showing an air knife of the plate glass processing apparatus according to the present invention, Figure 10 is a cross-sectional view showing an air knife of the plate glass processing apparatus according to the present invention.

The drying unit 170 is for drying the washing water remaining in the plate glass (G) processed while passing through the above-described polishing unit 130, washing unit 140, rinsing unit 150 to dry by spraying high pressure air. . The drying unit 170 includes a high pressure blower 171 for generating high pressure air, and an air knife 173 for spraying air supplied by the high pressure blower 171 on the surface of the plate glass G.

Here, the high pressure blower 171 is fixed to one side of the frame 110, the air knife 173 is installed adjacent to the surface of the plate glass (G) to be transferred. The air knife 173 has a residence space 175 in which air supplied from the high-pressure blower 171 stays is formed therein, and a rectangular nozzle for discharging air in the residence space 175 adjacent to the plate glass G ( 177) is formed.

Here, the rectangular nozzle 177 is formed to have a length corresponding to the width of the plate glass G, and the center portion is formed in a 'V' shape which protrudes in the opposite direction to the moving direction of the plate glass G. The reason for this is to allow air to be sprayed in the left and right directions with respect to the central portion of the rectangular nozzle 177 so that the washing water remaining in the plate glass G is moved in the left and right direction of the moving direction of the plate glass G.

On the other hand, the rectangular nozzle 177 is formed to be inclined in the moving direction of the plate glass (G) with respect to the surface of the plate glass (G). The reason for this is to increase the drying effect by injecting air in the direction opposite to the moving direction of the plate glass (G).

As described above, when the plate glass G is cleaned by the polishing unit 130, the washing unit 140, the rinse unit 150, and the drying unit 170, minute scratches or the like that may be damaged on the surface of the plate glass G may be removed. And, when the plate glass (G) is moved for cleaning when washing the plate glass (G) can be prevented from being contaminated again, the cleaning agent administered to the plate glass (G) for washing when washing the plate glass (G) and It is possible to prevent stains from remaining due to water or the like.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, The present invention may be modified in various ways. Therefore, modifications of the embodiments of the present invention will not depart from the scope of the present invention.

Claims (8)

A conveying unit for supplying and conveying plate glass,
A washing unit for washing the plate glass transferred by the transfer unit;
A rinse part for cleaning the plate glass passing through the washing part;
And a drying unit including a blower for generating high-pressure air and an air knife for injecting air supplied from the blower to the surface of the plate glass in order to dry the plate glass that has passed through the rinse unit. The method of claim 1, wherein the drying unit
Blower to generate high pressure air,
And an air knife for injecting air supplied from the blower to the surface of the plate glass. The method of claim 2, wherein the air knife,
A residence space in which air supplied from the blower resides,
And a rectangular nozzle having a central portion protruding in a direction opposite to the advancing direction of the plate glass. The method of claim 3, wherein the rectangular nozzle,
The plate glass processing apparatus characterized by inclining the advancing direction of the said plate glass and injecting air in the direction opposite to the advancing direction of the said plate glass. The method of claim 1,
Plate glass processing apparatus characterized in that it comprises a reservoir to precipitate and wash the water used in the rinse portion to be used in the washing unit. According to claim 1, wherein the cleaning unit
An upper washing unit for washing the upper surface of the plate glass;
And a lower surface washing unit for cleaning the lower surface of the plate glass. According to claim 1, wherein the rinse portion
An upper rinse portion for rinsing the upper surface of the plate glass;
And a lower surface rinse portion for rinsing the lower surface of the plate glass. The method of claim 5, wherein the reservoir
A plurality of rinse reservoirs for storing the washing water used in the rinse unit;
It is provided with a plurality of wash reservoirs in which the wash water used in the wash unit,
Each partition wall partitioning the rinse reservoir and the wash reservoir, the plate glass processing apparatus, characterized in that the leakage hole is formed to increase in height with respect to the traveling direction of the plate glass.

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