KR102505511B1 - Pre-processing Device for Ultra Thin Glass Delamination - Google Patents

Abstract

By spraying hot water to the side of the ultra-thin glass block in water, a water flow is formed between the ultra-thin glass and the UV curing resin so that the ultra-thin glass and the UV curing resin in the form of a film can be well separated. A hot water tank containing hot water, A table installed inside the hot water tank and loaded with rectangular plate-shaped ultra-thin glass blocks submerged on the upper surface, and a pair of tables installed facing each other in the water on both sides of the table to spray hot water toward both ends of the ultra-thin glass blocks loaded on the table. An ultra-thin glass pre-stripping apparatus comprising a first hot water nozzle pipe and a second hot water nozzle pipe is provided.

Description

Pre-processing Device for Ultra Thin Glass Delamination}

The present invention relates to an ultra-thin glass pre-stripping apparatus, and more particularly, by spraying hot water on the side of an ultra-thin glass block to separate the ultra-thin glass and UV curing resin prior to peeling the ultra-thin glass one by one. It relates to a pre-exfoliation treatment device.

In recent years, electrical and electronic technologies have developed rapidly, and various types of display products are emerging to meet the needs of the new era and various consumers, and among them, research on flexible displays that can fold and unfold the screen is active.

Accordingly, there is an increasing demand for flexible glass articles for use in various application products requiring flexible and bendable glass. For example, flexible display devices for mobile phones, tablets, and other portable electronic devices include flexible glass that must be bent or folded without breaking. However, glass has traditionally been considered rigid in nature, and therefore alternative materials for use in place of glass have been considered.

As a substitute for glass, polymer films made of polymer have been considered and studied for use in flexible display devices.

In the case of such a polymer film, mechanical strength is weak, and it merely serves to prevent scratches on a display panel, but is vulnerable to impact resistance, has a low transmittance, and is known to be relatively expensive.

On the other hand, in order to apply the glass to a flexible display product, it is known that if it is made of ultra thin glass (ultra thin glass) of 0.1 mm (100 μm) or less, it satisfies this requirement.

Ultra-thin glass is manufactured using a dip, spray, or dip & spray method, and is manufactured through a processing method such as polishing, but there is a high risk of damage due to breakage or cracking during the thinning process.

Accordingly, when processing processes such as cutting and polishing are performed by forming a plurality of ultra-thin glasses into blocks, cracks and breakage hardly occur. For example, when ultra-thin glass is laminated in multiple layers with UV (ultraviolet) curable resin coated between each of the ultra-thin glass and the UV curable resin is cured to form an integral ultra-thin glass block, cutting, polishing, etc. During the process, cracks or breakages rarely occur.

On the other hand, ultra-thin glass blocks require a peeling process to separate them into sheets of ultra-thin glass after performing processing processes such as cutting and polishing.

The object of the present invention is made in view of the above points, and by spraying hot water to the side of the ultra-thin glass block in water, a water flow is formed between the ultra-thin glass and the UV curing resin, and it is easy to separate the ultra-thin glass from the ultra-thin glass block one by one. Its purpose is to provide an ultra-thin glass peeling pretreatment device configured to be peeled off easily.

The ultra-thin glass peeling pretreatment apparatus proposed by the present invention includes a hot water tank in which hot water is accommodated, a table installed inside the hot water tank and loaded with rectangular plate-shaped ultra-thin glass blocks on the upper surface, and both sides of the table facing each other in the water. A first hot water nozzle pipe and a second hot water nozzle pipe are installed to inject hot water toward both end surfaces of the ultra-thin glass block loaded on the table.

The first hot water nozzle pipe and the second hot water nozzle pipe have a plurality of nozzle holes at regular intervals along their length, and as hot water is sprayed through the nozzle holes, a water flow is formed between the ultra-thin glass and the UV curing resin. As the surface resistance decreases between the ultra-thin glass and the UV curing resin, separation becomes easier.

Here, the first hot water nozzle pipe and the second hot water nozzle pipe are characterized in that hot water is supplied from the inside of the hot water tank and spraying is performed.

Further, the present invention may further include an aligning unit for aligning the ultra-thin glass blocks stacked on the table in a reference position by pushing them forward, backward, left and right.

The early part is installed to move back and forth in the front side of the table, and is installed to move back and forth while facing each other with a front align bar for pushing the ultra-thin glass block rearward and aligning it to a reference position, and facing each other with the front align bar at the rear side of the table. A rear alignment bar that aligns the glass block to the reference position by pushing it forward; a left alignment bar that is installed to move left and right on the left side of the table and pushes the ultra-thin glass block to the right to align it to the standard position; and a left and right alignment bar that moves left and right on the right side of the table. It is installed and includes a right align bar for aligning the ultra-thin glass block to the reference position by pushing the ultra-thin glass block to the left.

According to the ultra-thin glass separation pretreatment device according to an embodiment of the present invention, as a water flow is formed between the ultra-thin glass and the UV curing resin, a water film is generated between the ultra-thin glass and the UV curing resin, and the surface resistance is reduced, so that the ultra-thin glass is separated from the ultra-thin glass block one by one. It exfoliates well.

1 is a perspective view showing an ultra-thin glass peeling pretreatment apparatus according to an embodiment of the present invention.
2 is a plan view showing an ultra-thin glass peeling pretreatment apparatus according to an embodiment of the present invention.
3 is a side view illustrating an ultra-thin glass block used in an ultra-thin glass pre-stripping apparatus according to an embodiment of the present invention.
Figure 4 is a side cross-sectional view showing a table in the ultra-thin glass separation pretreatment apparatus according to an embodiment of the present invention.
5 is a plan view showing an array unit of an ultra-thin glass separation pretreatment device according to an embodiment of the present invention.
6 is a vertical cross-sectional view showing an array unit of an ultra-thin glass separation pretreatment device according to an embodiment of the present invention.
7 is a vertical side cross-sectional view showing an array unit of an ultra-thin glass separation pretreatment device according to an embodiment of the present invention.
8 is a vertical front cross-sectional view showing a first hot water nozzle pipe and a second hot water nozzle pipe of the ultra-thin glass pre-stripping treatment device according to an embodiment of the present invention.

Next, a preferred embodiment of the ultra-thin glass peeling pretreatment device according to the present invention will be described in detail with reference to the drawings.

Hereinafter, the same reference numerals are used for technical elements that perform the same function, and repeated detailed descriptions are omitted to avoid redundant description.

In addition, the examples described below are shown by way of example to effectively show preferred embodiments of the present invention, and should not be construed to limit the scope of the present invention.

As shown in FIGS. 1 to 3, the ultra-thin glass peeling pretreatment device according to an embodiment of the present invention is installed inside the hot water tank 10 in which hot water is accommodated, and the hot water tank 10, and has a square on the upper surface. A table 20 on which plate-shaped ultra-thin glass blocks 2 are loaded so as to be submerged, and an aligning unit 30 for aligning the ultra-thin glass blocks 2 stacked on the table 20 in front, rear, left, and right directions to a reference position; A pair of first hot water nozzle tubes 40 and a second pair of hot water nozzle pipes 40 installed facing each other in the water on both sides of the table 20 to spray hot water toward both end surfaces of the ultra-thin glass block 2 loaded on the table 20. It consists of a hot water nozzle pipe (50).

The hot water tank 10 is formed in a substantially rectangular tubular shape with an open upper surface.

Although not shown in the drawings, a heater may be installed in the hot water tank 10 to heat water.

Also, although not shown in the drawings, piping equipment for water supply, drainage, circulation, and the like may be installed in the hot water tank 10 .

The ultra-thin glass block 2 has a layer structure in which ultra-thin glass 3 is laminated in multiple layers and the UV curable resin 4 is cured with UV curable resin 4 disposed between the ultra-thin glass 3. .(see Fig. 3)

Here, the uppermost and lowermost layers of the ultra-thin glass block 2 may be made of dummy glass 5 thicker than the ultra-thin glass 3 .

As shown in FIG. 4 , the table 20 is installed in the inner center of the hot water tank 10 and is moved up and down by the up and down mover 22 .

The up-and-down moving table 22 includes a fixing base 23 having one side fixed to the hot water tank 10 or a base around the hot water tank 10, a moving base 24 slidably coupled to the fixing base 33, and It includes a connecting table 25 connecting the moving table 24 and the table 20.

The Shanghai Dongdae 22 raises the table 20 by the thickness of the ultra-thin glass 3 whenever the ultra-thin glass 2 is taken out so that the ultra-thin glass 3 located on the top floor is always at a constant height. .

As shown in FIGS. 5 to 7 , the aligning unit 30 is installed to move back and forth in the front side of the table 20 and pushes the ultra-thin glass block 2 rearward to align it to a reference position. ) and a rear alignment bar 34 installed at the rear of the table 20 so as to face each other and move back and forth with the front alignment bar 31 and pushing the ultra-thin glass block 2 forward to align it to a reference position; A left align bar 36 installed to move left and right on the left side of the table 20 and pushing the ultra-thin glass block 2 to the right to align it to a reference position, and installed to move left and right on the right side of the table 20, the ultra-thin glass block 2 It includes a right align bar 38 for aligning the glass block 2 to the reference position by pushing it to the left.

The front align bar 31, the rear align bar 34, the left align bar 36, and the right align bar 38 have a plurality of slits at regular intervals so that water (hot water) can pass through during movement. It can be provided vertically and long.

The front align bar 31, the rear align bar 34, the left align bar 36, and the right align bar 38 are connected to the hot water tank 10 or the hot water tank 10 through an extension arm 32 whose length is stretched. ) It is installed connected to the peripheral base and moves forward and backward according to the length change of the telescopic arm 32.

The extension arm 32 includes a fixed arm 32a, one side of which is fixed to the hot water tank 10 or a base around the hot water tank 10, and a moving arm 32b slidably coupled to the fixed arm 32a. made including

As shown in FIGS. 2, 6 and 8, the first hot water nozzle pipe 40 and the second hot water nozzle pipe 50 are installed on both left and right sides of the table 20, and although not shown in the drawings, the front and back It can also be installed on both sides.

The first hot water nozzle pipe 40 is installed long in front and rear on the left side of the table 20 and has a plurality of nozzle holes 42 at regular intervals on one side.

The second hot water nozzle pipe 50 is installed longitudinally on the right side of the table 20 and has a plurality of nozzle holes 42 at regular intervals on one side.

The first hot water nozzle pipe 40 and the second hot water nozzle pipe 50 contain ultra-thin glass 3 and film-type UV curable resin 4 as hot water is sprayed through the nozzle holes 42 and 52. It is characterized in that the ultra-thin glass 3 and the UV curable resin 4 are easily separated from each other while a space is formed as water flow is formed between them and the surface resistance between the ultra-thin glass 3 and the UV curable resin 4 decreases.

In the above, the preferred embodiment of the ultra-thin glass peeling pretreatment device according to the embodiment of the present invention has been described, but the present invention is not limited thereto, and it is possible to carry out various modifications within the scope of the claims, description of the invention, and drawings. And, this also falls within the scope of the present invention.

2: ultra-thin glass block 3: ultra-thin glass
4: UV curing resin 5: dummy glass
10: hot water tank 20: table
22: Dongdaemun Shanghai 23: Fixed stand
24: moving table 25: connecting table
30: alignment unit 31: front alignment unit
32: extension arm 34: rear alignment stand
36: left alignment stand 38: right alignment stand
40: first hot water nozzle pipe 50: second hot water nozzle pipe

Claims (5)

A hot water tank 10 in which hot water is accommodated;
A table 20 installed inside the hot water tank 10 and loaded with a square plate-shaped ultra-thin glass block 2 submerged on the upper surface;
A vertical and horizontal table 22 for moving the table 20 up and down;
An aligning unit 30 for aligning the ultra-thin glass block 2 stacked on the table 20 to a reference position by pushing it forward, backward, left and right;
A pair of first hot water nozzle tubes 40 and a second pair of hot water nozzle pipes 40 installed facing each other in the water on both sides of the table 20 to spray hot water toward both end surfaces of the ultra-thin glass block 2 loaded on the table 20. Including a hot water nozzle pipe 50,
The ultra-thin glass block 2 has a layer structure in which ultra-thin glass 3 is laminated in multiple layers and the UV curable resin 4 is cured, with UV curable resin 4 disposed between the ultra-thin glass 3. ,
The up-and-down moving table 22 includes a fixing base 23 having one side fixed to the hot water tank 10 or a base around the hot water tank 10, a moving base 24 slidably coupled to the fixing base 23, and It includes a connecting table 25 connecting the moving table 24 and the table 20, and every time a sheet of ultra-thin glass 3 is taken out, the table 20 is moved by the thickness of the ultra-thin glass 3. It is characterized by being raised so that the ultra-thin glass 3 located on the top layer always has a constant height,
The aligning unit 30 is installed to move forward and backward in the front side of the table 20, and includes a front align bar 31 that pushes the ultra-thin glass block 2 rearward to align it to a reference position, and a rear side of the table 20. The front aligner 31 faces each other and is installed to move back and forth, and the rear aligner 34 pushes the ultra-thin glass block 2 forward and aligns it to the reference position, and moves left and right on the left side of the table 20 The left align bar 36 is installed and aligns the ultra-thin glass block 2 to the right to the reference position by pushing the ultra-thin glass block 2 to the right, and is installed to move left and right on the right side of the table 20 by pushing the ultra-thin glass block 2 to the left. Including a right alignment bar 38 for aligning in position,
The first hot water nozzle pipe 40 and the second hot water nozzle pipe 50 are provided with a plurality of nozzle holes 42 and 52 at regular intervals along the length “‡ direction, and the nozzle holes 42, As hot water is sprayed through 52, a water flow is formed between the ultra-thin glass 3 and the UV curing resin 4, and the surface resistance between the ultra-thin glass 3 and the UV curing resin 4 is reduced.
The first hot water nozzle pipe (40) and the second hot water nozzle pipe (50) receive and spray hot water from the inside of the hot water tank (10). delete delete delete delete

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