KR101385132B1 - Apparatus for pressing a plate assembly - Google Patents

Abstract

At least one chamber including a body having a receptacle for receiving a plate assembly, an airtight holding unit positioned to be in close contact with the body, a loading unit for loading the plate assembly into the chamber, and connected to the chamber Disclosed is a pressurizing device including a pressurizing unit for injecting pressurized gas into a portion, and an exhaust unit connected to the chamber to exhaust pressurized gas injected into the receiving portion.

Description

Pressing device {Apparatus for pressing a plate assembly}

The present invention relates to a pressurization device.

In a flat panel display device such as an organic light emitting display device or a liquid crystal display device, a plate such as various functional films such as a polarizing film or an AR film may be attached to the plate outer surface of the display panel. In addition, a substrate plate made of glass or plastic such as a touch ITO substrate or a cover substrate may be attached.

The plate assembly to which the plate and the plate are attached so as to be in surface contact with each other needs to remove air bubbles between the plates.

In order to overcome the problems and / or limitations of the prior art as described above, an object of the present invention is to provide a pressurization device and a method capable of removing air bubbles between plates bonded to each other of a plate assembly.

Another object is to provide a pressurizing device and a method which allow a pressing process to be performed on a plurality of plate assemblies in a small space.

According to one aspect, the at least one chamber including a body having a receiving portion for receiving the plate assembly, an airtight holding unit positioned in close contact with the body, a loading unit for loading the plate assembly into the chamber, and the chamber It is connected to the pressurizing unit for injecting the pressurized gas to the receiving portion, and the pressurization device comprising a exhaust unit connected to the chamber for exhausting the pressurized gas injected into the receiving portion.

The chamber may include a tilting plate disposed to open and close an inlet communicating with the accommodation part and positioned inside the body, and may include a first hermetic holding unit interposed between the tilting plate and the body.

The tilting plate includes a first surface and a second surface facing each other, wherein the first surface faces the inlet, the second surface faces the receiving portion, and the first hermetic holding unit is provided with the first surface. It may be located between one surface and the body.

The first hermetic holding unit may be positioned to form a closed loop around the inlet.

The body has at least one opening, includes a cover plate coupled to the body to seal the opening, and may include a second hermetic holding unit interposed between the cover plate and the body.

The second hermetic holding unit may be positioned to form a closed loop about the opening.

It is possible to effectively remove air bubbles in the face bonded portion of the plate assembly in which at least two plates are face bonded.

The pressure loss in the pressurization chamber is small, the closing strength is automatically increased when the pressurization proceeds after the chamber is closed, and the pressing force can be maintained.

Installation assembly and maintenance can be simple.

It is possible to keep the airtight in the chamber stable.

When the plurality of chambers are arranged in an in-line manner, the process tack time can be significantly reduced because the loading and unloading process can be performed in another chamber even during the pressurized holding time.

Since the chambers can be stacked in a sheetwise direction perpendicular to the ground, the equipment can be made more compact and the volume of the entire equipment can be reduced.

1 is a configuration diagram schematically showing the configuration of a pressurization device according to an embodiment of the present invention,
2 is a plan view illustrating an example of a first chamber of FIG. 1;
3 is a partial side view illustrating an example of the first chamber of FIG. 1;
4 is a cross-sectional view illustrating an example of the first chamber of FIG. 1;
5A is a view showing an arrangement state of the first hermetic holding unit arranged around the entrance;
5B and 5C are views showing an arrangement state of the second hermetic holding unit arranged around the first opening and the second opening,
6 is a plan view illustrating another example of the first chamber of FIG. 1;
7 is a side view illustrating another example of the first chamber of FIG. 1;
8a to 8c is a configuration diagram sequentially showing the loading steps of the pressing device according to an embodiment of the present invention,
9A to 9C are diagrams sequentially illustrating unloading steps of the pressurizing device according to an embodiment of the present invention.

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

1 is a configuration diagram schematically showing a configuration of a pressing device according to an embodiment.

As can be seen in FIG. 1, the pressurization device according to an embodiment comprises a plurality of chambers 1, a loading unit 2, a pressurization unit 3 and an exhaust unit 4.

The chambers 1 may include a first chamber 11, a second chamber 12, a third chamber 13, and a fourth chamber 14 that are continuously arranged with each other. In the present invention, the chamber 1 may be provided with at least one, of course, it can be appropriately selected according to the process and pressure conditions.

In the present embodiment, the chambers 1, that is, the first chamber 11, the second chamber 12, the third chamber 13, and the fourth chamber 14 are stacked in a sheet shape in a direction perpendicular to the ground. Can be arranged. As the chambers 1 are stacked in this manner, the space in which the plurality of chambers 1 are disposed can be reduced, and the space can be more compactly utilized. However, the present invention is not necessarily limited thereto, but although not illustrated in the drawings, the chambers 1 may be disposed in a direction horizontal to the ground.

The loading part 2 is positioned to face at least one of the chambers 1. The loading unit 2 is provided to put the plate assembly in at least one of the chambers 1, and to remove the plate assembly from at least one of the chambers (1).

The loading unit 2 and the chambers 1 may be provided to move relative to each other. For example, the chambers 1 may be moved in the vertical direction while the loading part 2 is fixed, or the loading part 2 may be moved in the vertical direction while the chambers 1 are fixed. Can be. In the embodiment of the present invention to be described below, the chambers 1 are provided to be moved in the vertical direction while the loading part 2 is fixed. This makes it easier for the loading unit 2 and other equipment to perform a continuous process with each other.

Each chamber 1 is connected with a pressurizing unit 3 and an exhaust unit 4.

The pressurization unit 3 comprises a pressurization pump 31 and a plurality of pressurization valves 32. The pressure valve 32 is interposed between the pressure pump 31 and the respective chambers 1 to intervene the provision of pressurized gas supplied from the pressure pump 31 to the respective chambers 1. The pressurized gas is a gas for pressurizing the plate assembly accommodated in the chambers 1, and may be an inert gas such as nitrogen or argon, but is not limited thereto, and may be general air.

The pressure valve 32 includes a first pressure valve 321, a second pressure valve 322, a third pressure valve 323, and a fourth pressure valve 324. The first pressure valve 321 is interposed between the first chamber 11 and the pressure pump 31, and the second pressure valve 322 is between the second chamber 12 and the pressure pump 31. The third pressure valve 323 is interposed between the third chamber 13 and the pressure pump 31, and the fourth pressure valve 324 is the fourth chamber 14 and the pressure pump ( It is interposed between 31). In the embodiment according to FIG. 1, the pressure pump 31 is illustrated as one, but the present invention is not necessarily limited thereto, and a plurality of pressure pumps 31 are provided to be connected to different pressure pumps for each chamber 1. Can be.

The exhaust unit 4 comprises an exhaust pump 41 and a plurality of exhaust valves 42. The exhaust pump 41 forcibly exhausts the inside of the chambers 1. The exhaust valve 42 is interposed between the exhaust pump 41 and the respective chambers 1 to interrupt the exhaust of pressurized gas from the respective chambers 1. The present invention is not necessarily exhausted using the exhaust pump 41, and may be naturally exhausted by adjusting the opening and closing degree of the exhaust valve 42 without the exhaust pump 41.

The exhaust valve 42 includes a first exhaust valve 421, a second exhaust valve 422, a third exhaust valve 423, and a fourth exhaust valve 424. The first exhaust valve 321 is interposed between the first chamber 11 and the exhaust pump 41, and the second exhaust valve 422 is disposed between the second chamber 12 and the exhaust pump 41. The third exhaust valve 423 is interposed between the third chamber 13 and the exhaust pump 41, and the fourth exhaust valve 424 is the fourth chamber 14 and the exhaust pump ( It is interposed between 41). Although the exhaust pump 41 is illustrated as one in the embodiment according to FIG. 1, the present invention is not limited thereto, and a plurality of exhaust pumps 41 may be provided to be connected to different exhaust pumps for each chamber 1. Can be.

2 to 5c show an example of the first chamber 11, which is one of the chambers 1, in more detail. FIG. 2 is a plan view of the first chamber 11, and FIG. A partial side view of the first chamber 11, and FIG. 4 is a cross-sectional view of the first chamber 11. FIG. 5A is a view showing an arrangement state of the first hermetic holding unit 161 disposed around the inlet 112, and FIGS. 5B and 5C show the periphery of the first opening 111a and the second opening 111b. It is a figure which shows the arrangement state of the 2nd airtight holding | maintenance unit 162 (162 ') arrange | positioned at the inside.

The first chamber 11 has a body 111 having a receiving portion 113 therein. One side of the body 111 is provided with an inlet 112 communicating with the receiving portion 113. The plate assembly and / or the loading plate enter and exit the receptacle 113 through this inlet 112.

The inlet 112 is opened and closed by a tilting plate 114 installed in the body 111.

The tilting unit 15, which opens and closes the tilting plate 114, is located outside the first chamber 11.

The accommodating part 113 may include a first accommodating part 113a and a second accommodating part 113b communicated with each other.

The first accommodating part 113a is connected to the inlet 112 and functions as a loading chamber of the plate assembly and / or the loading plate accommodated into the accommodating part 113.

The second accommodating part 113b is connected to the pressurizing unit 3 and the exhaust unit 4, and functions as a pressurizing chamber of the plate assembly and / or the loading plate accommodated in the accommodating part 113.

The first accommodating part 113a and the second accommodating part 113b are partitioned by the body 111 integrally formed and communicate with each other through a communication path 113c formed in the body 111. Although not shown in the drawings, the body 111 may be separately manufactured by combining a body for forming the first accommodating part 113a and a body for forming the second accommodating part 113b.

The tilting plate 114 is located inside the body 111, one end of which is hinged to the inside of the body 111 to rotate toward the receiving portion 113 to open and close the inlet 112.

As shown in FIG. 4, the tilting plate 114 includes a first surface 114a and a second surface 114b facing each other, and the first surface 114a faces the inlet 112. The second surface 114b is disposed to face the receiving portion 113. The first surface 114a is provided to be in close contact with the side wall of the body 111 around the inlet 112 in a state where the inlet 112 is closed. As such, the tilting plate 114 is opened and closed in a manner of pivoting 90 degrees toward the inside of the body 111, that is, the first accommodating portion 113a, and closes around the inlet 112 while the inlet 112 is closed. Since the tilting plate 114 further pushes the side wall of the body 111 around the inlet 112 when the inside of the first chamber 11 is pressurized because the inside of the first chamber 11 is maintained in close contact with the body 111. Thus, the airtightness inside the first chamber 11 may be more firmly maintained.

The lower end of the tilting plate 114 is coupled to the tilting shaft 117 located inside the body 111. The tilting plate 114 rotates about the tilting shaft 117. The tilting shaft 117 is located below the first accommodating part 113a.

The tilting shaft 117 includes at least two detachable shafts 117a and a shaft connector 117b connecting the shafts 117a to each other. Accordingly, the tilting shaft 117 can be easily assembled and disassembled, and the maintenance can be simplified.

As shown in FIG. 4, the tilting shaft 117 is installed to extend the connecting frame 117d, and the connecting frame 117d is coupled to the second surface 114b of the tilting plate 114. Therefore, the connecting frame 117d rotates 90 degrees in the first accommodating portion 113a by the rotation of the tilting shaft 117, and thus the tilting plate 114 also rotates 90 degrees in the first accommodating portion 113a. To open and close the inlet 112.

As shown in FIG. 2, the tilting shaft 117 may be connected to at least one bearing housing 117c and the bearing housing 117c may be fixed to the bottom surface of the first accommodating part 113a. By the bearing housing 117c, the rotation of the tilting shaft 117 may be smoother and more stably fixed to the inner surface of the body 111.

A pair of tilting units 15 are installed at left and right sides of the inlet 112 of the body 111. The tilting unit 15 rotates the tilting shaft 117 to enable opening and closing of the tilting plate 114.

The tilting unit 15 includes a tilting bracket 151, a cylinder 152, and a link member 153.

The tilting bracket 151 is coupled to both sides of the body 111 and extends to protrude forward. Cylinders 152 are respectively coupled to the tilting bracket 151. Since the tilting bracket 151 protrudes to the front of the body 111, the tilting unit 15 may not be disturbed even during maintenance of the first accommodating part 113a.

One end of the link member 153 is connected to the tilting shaft 117 and the other end is connected to the piston 152a of the cylinder 152.

As the piston 152a of the cylinder 152 reciprocates, the link member 153 rotates, and the tilting shaft 117 rotates accordingly. As described above, the opening and closing operation of the tilting plate 114 is performed by the rotation of the tilting shaft 117.

The body 111 has at least one opening 111a, 111b, and further includes a cover plate 116 coupled to the body 111 to seal the opening 111a, 111b.

The cover plate 116 is formed of the first cover plate 116a and the first accommodating part 117a coupled to the upper part of the body 111 to cover the first opening 111a of the first accommodating part 117a. And second cover plates 116b coupled to both sides of the body 111 to cover the second openings 111b on both sides.

By the cover plate 116, the assembling of the tilting plate 114 and the tilting shaft 117 may be simplified, and maintenance may be easier.

On the other hand, the airtight holding unit is located in close contact with the body 111.

The hermetic holding unit may include a first hermetic holding unit 161 and a second hermetic holding unit 162, 162 ′.

As shown in FIG. 4, the first hermetic holding unit 161 is interposed between the tilting plate 114 and the body 111. For example, the first surface 114a of the tilting plate 114 may be positioned in contact with the body 111.

The first hermetic holding unit 161 may extend along the periphery of the inlet 112, for example, as shown in FIG. 5A, may be provided to form a closed curve extending along the periphery of the inlet 112. The first hermetic holding unit 161 is for preventing the pressurized gas from flowing out between the tilting plate 114 and the body 111 and may be formed of a resin material such as natural and / or synthetic rubber members or silicone. Can be. The first hermetic holding unit 161 may be installed in a manner of forming a groove having a predetermined depth in the first surface 114a of the tilting plate 114 and inserting it into the groove.

The second hermetic holding unit 162, 162 ′ is interposed between the cover plate 116 and the body 111 to seal the openings 111a and 111b formed in the body 111. That is, between the first cover plate 116a for sealing the first opening 111a and the body 111 and between the second cover plate 116b for sealing the second opening 111b and the body 111. The second hermetic holding units 162 and 162 'are interposed therebetween.

The second hermetic holding unit 162 which is interposed between the first cover plate 116a and the body 111 may extend along the periphery of the first opening 111a, as shown in FIG. 5B, for example. It may be provided to form a closed curve extending along the periphery of the first opening (111a).

The second hermetic holding unit 162 ′ interposed between the second cover plate 116b and the body 111 may extend along the periphery of the second opening 111b, for example as shown in FIG. 5C. It may be provided to form a closed curve extending along the periphery of the second opening (111b).

The second hermetic holding unit 162, 162 ′ is for preventing pressurized gas from flowing out between the first and second cover plates 116a and 116b and the body 111. It may be formed of a resin member such as a rubber member or silicone. The second hermetic holding unit 162, 162 ′ forms a groove having a predetermined depth on a surface of the first and second cover plates 116a and 116b facing the body 111 and inserts the groove into a predetermined depth. Can be installed as

On the other hand, although not shown in the drawings, the plate assembly and / or the loading plate to enter into the second receiving portion (113b) is arranged in a plurality of rollers protruding upward in the second receiving portion (113b) inside the body (111) Can support the bottom of the.

As shown in FIG. 1, the structure of the first chamber 11 may be equally applied to the second chamber 12 to the fourth chamber 14.

6 and 7 are a plan view and a side view of another example of the first chamber 11.

Unlike the above-described embodiment, the tilting bracket 151 is coupled to both sides of the body 111 and extends rearwardly. Therefore, unlike the above-described embodiment, the third cover plate 116c is coupled to the body 111 to seal the opening 111c of the rear surface of the body 111 instead of including the second cover plates on both sides of the body 111. . This embodiment can reduce the overall length of the body 111 can take a more compact installation structure. A second hermetic holding unit may be installed between the third cover plate 116c and the body 111 around the opening 111c. Other components are the same as the above-described embodiment, and thus will be omitted.

Next, a pressing method of the pressing device according to an embodiment of the present invention according to FIGS. 1 to 5C described above with reference to FIGS. 8A to 9C will be described.

First, as shown in FIG. 8A, the first plate assembly 71 proceeds in the loading direction Y1 and is received into the first chamber 11. Although only the first plate assembly 71 is shown in the drawing, this is for convenience of description and as described above, the first plate assembly 71 is seated on a loading plate, and the loading plate is inserted into the first chamber 11. Can be accommodated. The same is true of the other plate assemblies described below.

After the first plate assembly 71 is received in the first chamber 11, as shown in FIG. 4, the tilting plate 114 is closed to close the inlet 112 of the first chamber 11.

1, the pressurization pump 31 of the pressurization unit 2 is operated and the first pressurization valve 321 is opened to supply pressurized gas to the first chamber 11. At this time, the second pressure valve 322 to the fourth pressure valve 324 and the plurality of exhaust valves 42 are in a closed state.

When the inside of the first chamber 11 is supplied with a suitable pressure by supplying the pressurized gas, the first pressurizing valve 321 is closed to stop the supply of the pressurized gas into the first chamber 11 and the first chamber 11 is closed. Becomes confidential. The first chamber 11 is maintained for a predetermined time in this state to maintain the pressure therein to continuously press the first plate assembly 71 accommodated therein. When the inside of the first chamber 11 is maintained at a predetermined pressure by the pressurized gas, the pressure presses the first plate assembly 71 in the plane direction. Thus, bubbles between the plates forming the first plate assembly 71 can be removed.

Meanwhile, while the first chamber 11 is kept airtight, as shown in FIG. 8B, the second plate assembly 72 is positioned in a loading unit (not shown) located in front of the first chamber 11. . In this state, the chambers 1 move up one step so that the second plate assembly 72 is positioned in front of the second chamber 12.

Next, as can be seen in FIG. 8C, the second plate assembly 72 proceeds in the loading direction Y1 and is received into the second chamber 12.

After the second plate assembly 72 is received in the second chamber 12, the second chamber 12 is closed.

1, the pressurization pump 31 of the pressurization unit 2 is operated and the second pressurization valve 322 is opened to supply pressurized gas to the second chamber 12. At this time, the first pressure valve 321, the third pressure valve 323, the fourth pressure valve 324, and the plurality of exhaust valves 42 are closed.

When the inside of the second chamber 12 reaches a proper pressure by supplying the pressurized gas, the second pressurizing valve 322 is closed to stop the supply of the pressurized gas into the second chamber 12 and the second chamber 12 is closed. Becomes confidential. The second chamber 12 is maintained in this state for a certain time to maintain a pressure therein to continuously press the second plate assembly 72 accommodated therein.

In this manner, the plate assemblies are also accommodated in the third chamber 13 and the fourth chamber 14 and the pressing process can proceed. As such, the present invention can continue the process of receiving the plate assembly in another chamber while the pressurization process, which requires a certain time to be maintained in a specific chamber, can minimize the tack time loss due to the pressurization time, and can be inlined. It is possible to maintain the pressurization process in a manner.

After the chambers are kept in the state in which the plate assemblies are filled in a predetermined time, the process of sequentially removing the plate assemblies from the respective chambers is performed.

First, with the positions of the chambers 1 adjusted so that the first chamber 11 again corresponds to the loading unit, as shown in FIG. 1, the first exhaust valve 42 of the exhaust unit 4 ) Is opened and the inside of the first chamber 11 is exhausted. At this time, the exhaust pump 41 can be operated to forcibly evacuate.

When the inside of the first chamber 11 is exhausted, as shown in FIG. 9A, the first chamber 11 is opened and the first plate assembly 71 is moved in the unloading direction Y2 to be discharged. After discharge, it is transported outward.

As shown in FIG. 9B, after the discharge of the first plate assembly 71 is completed, the chambers 1 are raised and the second chamber 12 is moved to a position corresponding to the loading unit. As can be seen in FIG. 1, the second exhaust valve 42 of the exhaust unit 4 is opened to exhaust the inside of the second chamber 12. At this time, the exhaust pump 41 can be operated to forcibly evacuate.

When the inside of the second chamber 12 is exhausted, as shown in FIG. 9C, the second chamber 12 is opened and the second plate assembly 72 is discharged. After discharge, it is transported outward.

In this way, the plate assemblies are continuously discharged from the respective chambers.

In the above-described embodiment, the plate assembly is sequentially received in each of the chambers, and then the plate assembly is sequentially discharged from each of the chambers, but the present invention is not necessarily limited thereto. The plate assembly may be discharged from the pressurized chamber before the plate assembly is received.

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 and that those skilled in the art will recognize that various modifications and equivalent arrangements may be made therein. It will be possible. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

Claims (6)

At least one chamber having a receiving portion for receiving a plate assembly, the body having an inlet communicating with the receiving portion at one side, and an airtight holding unit positioned to be in close contact with the body;
A loading unit for loading the plate assembly into the chamber;
A pressurizing unit connected to the chamber to inject pressurized gas into the receiving part; And
And an exhaust unit connected to the chamber to exhaust the pressurized gas injected into the accommodation portion.
The accommodating portion includes a first accommodating portion connected to the inlet and a second accommodating portion coupled to communicate with the first accommodating portion to accommodate the plate assembly transferred through the first accommodating portion and connected to the pressurizing unit and the exhaust unit. and,
The chamber further includes a tilting plate coupled to the inside of the body to open and close the inlet and positioned at the first accommodation portion, and a tilting shaft coupled to the tilting plate and positioned at the first accommodation portion,
The body has at least one opening in a position corresponding to the first receiving portion, the pressing device including a cover plate detachably coupled to the body to seal the opening. The method of claim 1,
And a first hermetic holding unit interposed between the tilting plate and the body. 3. The method of claim 2,
The tilting plate includes a first surface and a second surface facing each other, the first surface is disposed facing the inlet, the second surface facing the receiving portion, the first hermetic holding unit Pressing device located between one side and the body. The method of claim 3,
The first hermetic holding unit is positioned to form a closed loop around the inlet. 5. The method according to any one of claims 1 to 4,
And a second hermetic holding unit interposed between the cover plate and the body. 6. The method of claim 5,
And the second hermetic holding unit is positioned to form a closed loop about the opening.

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