KR102659133B1 - Patterned etched glass manufacturing device using sandblasting technique - Google Patents

Abstract

The present invention relates to an apparatus for manufacturing patterned etched glass using a sandblasting technique. The composition of the present invention includes a sandblaster that sprays sandblasting etching particles, a support roller installed extending left and right from the rear of the sandblaster, and , a roller conveyor installed below the support roller, a drive motor for rotationally driving the roller conveyor, a metal plate placed on the roller conveyor and supported by the support roller and transported by the roller conveyor, and the metal plate. In order to form a pattern on the glass mounted on the plate, a metal mask for pattern formation installed on the front of the glass, and a metal mask for pattern formation attached to the metal plate and installed on the front of the glass are pulled by magnetic force. It includes a magnet that presses and secures the glass to the metal plate.

Description

Patterned etched glass manufacturing device using sandblasting technique}

The present invention relates to an apparatus for manufacturing etched glass using a sandblasting technique. More specifically, the metal mask for pattern formation is firmly fixed to the glass using a magnet, thereby forming a metal mask for pattern formation by spraying pressure of sandblasting etching particles. A patterned etched glass manufacturing device using the sandblasting technique that can reduce the defect rate by preventing the pattern forming mask from being pushed out, and can determine the aging of the pattern forming metal mask by measuring the impedance of the flange, which is the same material as the pattern forming metal mask. It's about.

Sandblasting, one of the glass manufacturing techniques, is a technique that processes the glass surface by spraying sand.

Etched glass is made by carving the glass surface using this sandblasting technique. It disperses light, blocks the line of sight, and has a translucent lighting effect, so it is widely used for interior decoration, including bathrooms, verandas, entrances, and living rooms in general homes.

For reference, the technology for etching glass using this sandblasting technique includes a particle spraying step in which a particle sprayer sprays sandblasting etching particles; A sandblasting etching step in which a roller moves heat-strengthened glass placed on a glass supporter at a constant speed within the particle sprayer to sandblast and etch the surface of the heat-strengthened glass; And a cleaning step in which a cleaner sprays a cleaning solution to clean the sand blast-etched heat-strengthened glass. A technology including "Sand" in Korean Patent Publication No. 10-2023-0005649 (publication date January 10, 2023) It was disclosed in “Method of manufacturing heat-strengthened glass for solar modules by blasting etching.”

Recently, the demand for patterned etched glass is increasing as patterned etched glass, which adds patterns to etched glass rather than simply etched glass, has been developed.

However, the conventional etched glass manufacturing apparatus using the sandblasting technique has a problem in that the glass cannot be firmly fixed during the patterned etched glass production process, resulting in a high defect rate.

Public Patent Publication No. 10-2023-0005649

The purpose of the present invention is to solve the conventional problems as described above. By firmly fixing the metal mask for pattern formation to the glass using a magnet, the metal mask for pattern formation is not pushed by the spray pressure of the sandblasting etching particles. The aim is to provide a patterned etched glass manufacturing device using a sandblasting technique that can reduce the defect rate by preventing defects from forming.

Another object of the present invention is to provide an apparatus for manufacturing patterned etched glass using a sandblasting technique, which allows determining the aging of a metal mask for pattern formation by measuring the impedance of a flange made of the same material as the metal mask for pattern formation. there is.

As a means to achieve the above object, the present invention includes a sand blaster that sprays sand blasting etching particles, a support roller installed to extend left and right from the rear of the sand blaster, and a lower part of the support roller. a roller conveyor, a drive motor for rotating the roller conveyor, a metal plate placed on the roller conveyor and supported by a support roller and transported by the roller conveyor, and a pattern on the glass mounted on the metal plate. In order to form a pattern-forming metal mask installed on the front of the glass, and attached to the metal plate, the pattern-forming metal mask installed on the front of the glass is pulled by magnetic force so that the glass is pressed and fixed to the metal plate. It is desirable if it includes a magnet.

In the configuration of the present invention, line grooves for attaching a magnet are formed on the front surface of the metal plate at regular intervals, and the depth of the line grooves is preferably the same as or deeper than the thickness of the magnet.

In the configuration of the present invention, it is preferable that the metal plate is formed at the bottom with a support line portion on which glass and a metal mask for pattern formation can be placed.

The configuration of the present invention further includes a sensing unit for detecting aging of the metal mask for pattern formation, wherein the sensing unit includes a flange assembly installed on one end of the metal mask for pattern formation, and the flange assembly and the metal mask for pattern formation. It is preferable to include an impedance detection unit installed between the masks and detecting the impedance of the flange assembly, a conversion unit connected to the impedance detection unit, and a control unit connected to the conversion unit.

The configuration of the present invention is that the flange assembly is made of the same material as a metal mask for pattern formation and is formed in a ring shape, including a first flange with a bolt portion protruding, and a ring shape with a cross section in the shape of "ㅗ". It is formed in a ring shape and has a hole through which the bolt of the first flange passes, an elastic plate that is in close contact with the first flange, and a hole through which the bolt of the first flange passes is formed and is in close contact with the elastic plate. It is preferable to include a second flange and a nut that is screwed to the bolt portion of the first flange and comes into close contact with the second flange so that the first flange and the second flange press the elastic plate.

The configuration of the present invention is that the impedance detection unit includes a first measuring plate whose one side is in contact with one side of the first flange, a second measuring plate whose one side is in contact with the other side of the first flange, and the first measuring plate. and an insulator that insulates the second measurement plate and insulates the area of the flange assembly that does not surround the first measurement plate and the second measurement plate, and at least a portion of the first flange that surrounds the first measurement plate, the second measurement plate, and the insulator. It is preferable to include a cover part clamped to the area and a corrosion prevention part coated while surrounding the outer surface of the cover part.

The present invention uses a magnet and a metal mask for pattern formation to firmly fix the glass, thereby preventing the metal mask for pattern formation from being pushed out by the injection pressure of sandblasting etching particles, thereby reducing the defect rate, and reducing the defect rate by using a metal mask for pattern formation. It has the effect of allowing the aging of the metal mask for pattern formation to be determined by measuring the impedance of the flange, which is made of the same material.

Figure 1 is a perspective view of a patterned etched glass manufacturing apparatus using a sandblasting technique according to an embodiment of the present invention.
Figure 2 is a front view of a patterned etched glass manufacturing apparatus using a sandblasting technique according to an embodiment of the present invention.
Figure 3 is a side cross-sectional view of a patterned etched glass manufacturing apparatus using a sandblasting technique according to an embodiment of the present invention.
Figure 4 is a configuration diagram of the sensing unit of the patterned etched glass manufacturing apparatus using the sandblasting technique according to an embodiment of the present invention.

Hereinafter, in order to explain the present invention in detail so that a person skilled in the art can easily practice the present invention, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Other purposes, features, and operational advantages, including the purpose, operation, and effect of the present invention, will become clearer through the description of the preferred embodiment.

For reference, the embodiments disclosed herein are merely presented by selecting the most preferred embodiments from among various possible embodiments to aid the understanding of those skilled in the art, and the technical idea of the present invention is not necessarily limited or restricted only to the presented embodiments. Rather, various changes, additions, and changes, including equivalents and substitutes, are possible without departing from the technical spirit of the present invention.

In addition, the terms and expressions of words used in the specification and claims of the present application are defined based on the principle that the inventor can appropriately define the concept of the term in order to explain the invention in the best way. , it should not be construed as limited to the usual or dictionary meaning, but should be interpreted as meaning and concept consistent with the technical idea of the present invention. As an example, singular expressions include plural expressions unless the context clearly indicates otherwise, and expressions regarding direction are set based on the position expressed in the drawing for convenience of explanation, and are set as “connected” or “installed.” The expression “becomes possible” includes not only direct connection or installation, but also connection or installation through other intermediate components.

Figure 1 is a perspective view of an apparatus for manufacturing patterned etched glass using a sandblasting technique according to an embodiment of the present invention, and Figure 2 is a front view of an apparatus for manufacturing patterned etched glass using a sandblasting technique according to an embodiment of the present invention. Figure 3 is a side cross-sectional view of a patterned etched glass manufacturing apparatus using a sandblasting technique according to an embodiment of the present invention.

As shown in Figures 1 to 3, the structure of the patterned etched glass manufacturing apparatus using the sandblasting technique according to an embodiment of the present invention includes a sand blaster 10 that sprays sandblasting etching particles, and the sand A support roller 20 installed to extend left and right from the rear of the blaster 10, a roller conveyor 30 installed below the support roller 20, and a drive motor for rotating the roller conveyor. (40), a metal plate 50 placed on the roller conveyor 30 and supported by a support roller 20 and transported by the roller conveyor 30, and a glass mounted on the metal plate 50 ( A pattern forming metal mask 60 installed on the front of the glass (G) to form a pattern on G, attached to the metal plate 50 and installed on the front of the glass (G). It includes a magnet 70 that pulls the metal mask 60 with magnetic force so that the glass G is pressed and fixed to the metal plate 50.

A control and display panel 11 is installed on the front of the sand plaster 10.

The metal plate 50 is formed with line grooves 51 at regular intervals for attaching the magnet 70 to the front, and the depth of the line groove 51 is equal to or deeper than the thickness of the magnet 70. is formed

The metal plate 50 is formed at the bottom with a support line portion 52 on which the glass G and the metal mask 60 for pattern formation can be placed.

Figure 4 is a configuration diagram of the sensing unit of the patterned etched glass manufacturing apparatus using the sandblasting technique according to an embodiment of the present invention.

As shown in FIG. 4, the sensing unit of the patterned etched glass manufacturing apparatus using the sandblasting technique according to an embodiment of the present invention includes flange assemblies 711 and 712 installed at one end of the metal mask 60 for pattern formation. 713, 714) and a device installed between the flange assemblies (711, 712, 713, 714) and the metal mask 60 for pattern formation and detecting the impedance of the flange assemblies (711, 712, 713, 714). It includes an impedance detection unit 72, a conversion unit 73 connected to the impedance detection unit 72, and a control unit 74 connected to the conversion unit 73.

The flange assemblies (711, 712, 713, 714) are made of the same metal material as the metal mask 60 for pattern formation and are formed in a ring shape, and include a first flange ( 711) and an elastic plate ( 72), and a second flange 713 that is formed in a ring shape and has a hole through which the bolt 711a of the first flange 711 passes and is in close contact with the elastic plate 712, and the first flange 711. It includes a nut 714 that is screwed to the bolt portion 711a and comes into close contact with the second flange 713 so that the first flange 711 and the second flange 713 press the elastic plate 712. .

The impedance detection unit 72 is coupled between the flange assemblies (711, 712, 713, 714) and the metal mask 60 for pattern formation to detect the impedance of the flange assemblies (711, 712, 713, 714). The impedance detection unit 72 includes a first measurement plate 721, a second measurement plate 722, an insulator 723, a cover portion 724, and a corrosion prevention portion 725.

One side of the first measuring plate 721 is in contact with one side of the first flange 711. In this case, the first measurement plate 721 is electrically connected to the first wiring connected to the conversion unit 80. The outer surface of the first wiring is insulated by being wrapped with an insulating coating. This first measuring plate 721 is in contact with the entire side of the first flange 711 and is formed to measure the impedance between the thickness region of the first flange 711 together with the second measuring plate 722. .

One side of the second measuring plate 722 is in contact with the other side of the first flange 711. In this case, the second measurement plate 722 is electrically connected to the second wiring connected to the conversion unit 80. The outer surface of the second wiring is insulated by being wrapped with an insulating coating. This second measuring plate 722 is in contact with the entire other side of the first flange 711 and measures the impedance between the first measuring plate 721 and the thickness region of the first flange 711.

The first measuring plate 721 and the second measuring plate 722 are formed to cover both sides of the first flange 711, so that some areas of the first flange 711 are corroded and the impedance changes due to a change in thickness. The value is detected.

The first measuring plate 721 and the second measuring plate 722 may be made of an oxidation-resistant aluminum material.

The insulator 723 insulates the first measurement plate 721 and the second measurement plate 722, and the area of the flange assembly 71 that does not surround the first measurement plate 721 and the second measurement plate 722 is insulated. Additionally, the insulator 723 not only insulates the first measurement plate 721 and the second measurement plate 722 but also prevents corrosion from occurring.

The cover portion 724 surrounds the first measurement plate 711, the second measurement plate 722, and the insulator 723 and is clamped to at least a partial area of the first flange 711. A portion of the cover portion 724 is compressed to couple the first measurement plate 721, the second measurement plate 722, and the insulator 723 to the first flange 711, thereby forming the first measurement plate 721. ) and the second measuring plate 722 are fixed so as not to flow.

The corrosion prevention portion 725 is coated surrounding the outer surface of the cover portion 724. This corrosion prevention portion 725 may be made of an insulating material such as epoxy. The corrosion prevention part 725 prevents corrosion of the cover part 724 and prevents the measurement performance of the first measuring plate 721 and the second measuring plate 722 from changing.

The operation of the patterned etched glass manufacturing apparatus using the sandblasting technique according to an embodiment of the present invention with the above configuration is as follows.

The operator evenly arranges and attaches the magnets 70 to the line grooves 51 of the metal plate 50 placed on the roller conveyor 30.

Next, the operator places the glass G on the support line portion 52 of the metal plate 50 so that the glass G is placed on the front surface of the metal plate 50.

Next, the operator places the metal mask 60 for pattern formation on the support line portion 52 of the metal plate 50 so that the metal mask 60 for pattern formation is disposed on the entire surface of the glass G.

Next, the operator operates the patterned etched glass manufacturing device by manipulating the control of the sand plaster 10 and the display panel 11.

When the patterned etched glass manufacturing device is operated, the drive motor 40 rotates, and the rotational driving force is transmitted to the roller conveyor 30 connected to the drive motor 40, causing the roller conveyor 30 to rotate clockwise.

When the roller conveyor 30 rotates clockwise, the metal plate 50 placed on the roller conveyor 30 is transferred to the right, and the glass (G) fixed to the front of the metal plate 50 and the pattern are formed. The metal mask 60 is transferred to the right along with the metal plate 50. At this time, the support roller 20 supports the metal plate 50 while minimizing friction with the metal plate 50, so that the metal plate 50, the glass (G), and the metal mask 60 for pattern formation are smoothly transferred. make it possible

When the metal plate 50, the glass G, and the metal mask 60 for pattern formation are transferred and entered into the rear of the sand blaster 10 and then stopped, sand blasting etching particles are sprayed from the sand blaster 10.

In this way, when the sand blasting etching particles are sprayed from the sand blaster 10, the portion that is not masked by the metal mask 60 for pattern formation of the glass (G) becomes opaque as the surface is etched, and the metal mask ( The portion masked by 60) is maintained in a transparent state, thereby producing a patterned etched glass having the same pattern as that of the metal mask 60 for pattern formation in the glass G.

At this time, because the pressure of the sand blasting etching particles sprayed from the sand blaster 10 is very high, if the fixed state between the glass (G) and the metal mask 60 for pattern formation is not stable, the metal mask 60 for pattern formation may be damaged. As it is pushed out, the pattern formed on the glass (G) is not neatly formed, resulting in defective products. The magnet 70 of the present invention uses the metal mask 60 for pattern formation to press the glass (G) to form a pattern. The metal mask 60 is stably pressed and fixed to the glass (G).

After the sand blasting etching particles are completely sprayed from the sand blaster 10, the drive motor 40 and the roller conveyor 30 are operated again, and the metal plate 50, the glass (G), and the metal mask 60 for pattern formation are formed. is released from the sand blaster (10).

In this way, when the metal plate 50, the glass G, and the metal mask 60 for pattern formation are removed from the sand blaster 10 and stopped, the operator separates the pattern-etched glass glass G.

Meanwhile, the impedance detection unit 72 of the sensing unit detects the impedance of the thickness area of the first flange 711 of the flange assemblies 711 to 714, and the conversion unit 73 converts the detected impedance into a digital value. Then, when the first flange 711 is corroded and the impedance value changes by transmitting it to the control unit 74, the changed impedance change value is detected through the first measurement plate 721 and the second measurement plate 722. You can do it.

When the digital value of the impedance of the flange assemblies 711 to 714 exceeds a preset value, the control unit 74 controls the aging of the metal mask 60 for pattern formation through the control and display panel 11 of the sand blaster 10. By displaying a signal, the operator can replace the metal mask 60 for forming a new pattern.

10: Sand blaster 20: Support roller
30: roller conveyor 40: drive motor
50: Metal plate 60: Metal mask for pattern formation
70: Magnet G: Glass

Claims (6)

A sand blaster that sprays sand blasting etching particles,
A support roller installed to extend left and right from the rear of the sand blaster,
A roller conveyor installed below the support roller,
A drive motor for rotating the roller conveyor,
A metal plate placed on the roller conveyor and supported by a support roller and transported by the roller conveyor;
a metal mask for pattern formation installed on the front of the glass to form a pattern on the glass mounted on the metal plate;
A magnet attached to the metal plate, which presses and fixes the glass to the metal plate by magnetically pulling the pattern-forming metal mask installed on the front of the glass;
It includes a sensing unit for detecting aging of the pattern forming metal mask,
The sensing unit,
A flange assembly installed on one end of a metal mask for pattern formation,
an impedance detection unit installed between the flange assembly and the metal mask for pattern formation and detecting the impedance of the flange assembly;
A conversion unit connected to the impedance detection unit,
It includes a control unit connected to the conversion unit,
The flange assembly is,
A first flange made of the same material as a metal mask for pattern formation and formed in a ring shape with a bolt portion protruding;
An elastic plate that is formed in a ring shape with a "ㅗ" shaped cross section and has a hole through which the bolt portion of the first flange passes, and is in close contact with the first flange,
A second flange is formed in a ring shape, has a hole through which the bolt of the first flange passes, and is in close contact with the elastic plate,
A device for manufacturing patterned etched glass using a sandblasting technique, characterized in that it includes a nut that is screwed to the bolt portion of the first flange and comes into close contact with the second flange so that the first flange and the second flange press the elastic plate. According to clause 1,
The metal plate has line grooves formed at regular intervals on the front for attaching a magnet,
A patterned etched glass manufacturing device using a sandblasting technique, characterized in that the depth of the line groove is formed deeper than or equal to the thickness of the magnet. According to clause 1,
A device for manufacturing patterned etched glass using a sandblasting technique, wherein the metal plate has a support line at the bottom on which glass and a metal mask for pattern formation can be placed. delete delete According to clause 1,
The impedance detection unit,
a first measuring plate whose one side is in contact with one side of the first flange, and a second measuring plate whose one side is in contact with the other side of the first flange;
an insulator that insulates the first measurement plate and the second measurement plate and insulates a region of the flange assembly that does not surround the first measurement plate and the second measurement plate;
a cover portion surrounding the first measuring plate, the second measuring plate, and an insulator and clamped to at least a portion of the first flange;
A device for manufacturing patterned etched glass using a sandblasting technique, comprising an anti-corrosion part coated while surrounding the outer surface of the cover part.