KR100464849B1 - Liquid Crystal Injection Port Encapsulation Press - Google Patents

Abstract

By making the base metal larger than the maximum size of the cell that can be put in the pressurizing chamber and using the base metal universally regardless of the size of the cell that is put in the pressurizing chamber, the liquid crystal inlet encapsulation process time due to the replacement of the base metal This can be prevented from increasing.

In addition, by uniformly pressing the entire area of the cell, it is possible to prevent the cell gap failure due to the height difference of the cell gap to improve the reliability of the product.

Description

Liquid Crystal Injection Port Encapsulation Press

The present invention relates to a press for encapsulating a liquid crystal inlet. More specifically, the base gap of the liquid crystal injection hole is designed to be slightly larger than the maximum size of a cell that can be introduced into the pressure chamber in an end seal process, thereby reducing the cell gap of the LCD panel. The present invention relates to a press for sealing a liquid crystal injection hole uniformly controlled.

In general, the LCD panel includes a thin film transistor substrate (hereinafter referred to as a TFT substrate), a color filter substrate facing the TFT substrate, and a liquid crystal material injected between the two substrates, and thus the electro-optic of the liquid crystal inserted therein. Display device using properties.

Here, in order to inject a liquid crystal material between the TFT substrate and the color filter substrate, a spacer is added along the edge of the color filter substrate except for a predetermined portion, and then the TFT substrate and the color filter substrate are aligned. Thereafter, the aligned TFT substrate and the color filter substrate are moved to a hot press facility to apply a predetermined pressure and heat to the TFT substrate and the color filter substrate to cure the yarn, thereby forming a cell gap having a predetermined height between the TFT substrate and the color filter substrate. do.

As such, when the yarn is cured by heat and pressure, the TFT substrate and the color filter substrate are cut to size, and then the liquid crystal is injected into the cell gap through a predetermined portion, that is, the liquid crystal injection hole, where the seal is not printed. Thereafter, the ultraviolet curable material is printed on the liquid crystal inlet and the liquid crystal inlet is sealed by using a liquid crystal inlet encapsulation press to prevent the liquid crystal from leaking out.

The liquid crystal injection hole encapsulation press includes a press chamber for encapsulating the liquid crystal injection hole, a cell jig inserted into the pressure chamber while supporting a predetermined area of the cell by opening a predetermined area of the lower surface and accommodating the cell, and a pressure chamber. The guide holder is formed at the edge of the guide to guide the cell jig to the proper position of the pressure chamber, and is installed at the lower part of the pressure chamber corresponding to the part where the cell is placed and is designed to be smaller in size than the cell so that a predetermined area of the upper surface is pressed. It consists of a base metal flowing into the chamber.

When the liquid crystal injection hole encapsulation press device configured as described above is stacked with a plurality of metal spacers, paper, and cells (for example, 12.1 inch size) in the storage space of the cell jig, the cell jig is introduced into the pressing stage. Place it in the guide and place the cell on top of the base metal. Then, when the cylinder presses the metal spacer and the cell is irradiated with ultraviolet rays, the cell seals the liquid crystal injection hole by curing the ultraviolet curable material by the ultraviolet light while maintaining the cell gap of a predetermined height by the uniform force transmitted from the metal spacer and the base beal. do.

However, since the size of the base metal is smaller than the size of the cell housed in the cell jig, the base metal, which transfers the uniform force to the cell while supporting the cell each time the size of the cell is changed, is also replaced according to the size of the cell. Is increased. In addition, since the size of the base metal is smaller than the size of the cell, a predetermined area is not supported by the base metal along the edge of the cell, resulting in cell gap defects having different cell gap heights at the edge of the cell and at the center. .

Accordingly, an object of the present invention has been made in view of the above problems, and to reduce the working time of the liquid crystal injection hole sealing process by using the base metal universally regardless of the size of the cell accommodated in the cell jig. .

Another object of the present invention is to prevent the occurrence of cell gap failure by always increasing the size of the base metal than the size of the cell accommodated in the cell jig.

Other objects of the present invention will become more apparent from the following detailed description and the accompanying drawings.

In order to achieve the above object, the present invention is provided with a cylinder for pressurizing the cell on the upper side is formed in the pressurizing chamber and the process of the process, and larger than the cell of the maximum size to be put into the pressurizing chamber is installed on the lower surface of the pressurizing chamber And a cell jig having a base metal and a storage space disposed on the base metal and accommodating cells therein.

Preferably, the base metal is designed to be about 10% larger than the largest size cell.

Hereinafter, the liquid crystal injection hole encapsulation press according to the present invention will be described in detail with reference to the accompanying drawings.

As shown in the pressure chamber 110 in which the liquid crystal injection hole encapsulation process is performed, the base metal 120 supporting the cell 152 and transmitting a uniform force to the cell 152 and the upper portion of the base metal 120. The cell jig 130 placed in the cell 152 and the cylinder 140 for pressing the cell 152 are installed.

Here, the base metal 120 is installed on the lower surface of the pressure chamber 110, the base metal 120 is designed to be larger than the maximum size of the cell 152 that can be injected into the pressure chamber 110. Preferably, the size of the base metal 120 is about 10% larger than the size of the maximum cell 152 that can be injected into the pressure chamber 110.

The cell jig 130 has a shape corresponding to that of the cell 152, and an accommodating space is formed such that one cell 152 of the same size is accommodated through the open top surface and the cell jig 130 is formed. The bottom surface of) is completely closed to make direct contact with the base metal 120.

On the other hand, at least one cylinder 140 is installed on the upper surface of the pressurization chamber 110. Here, reference numeral 154 denotes a metal spacer that buffers the pressing force in the cylinder 140 and transmits a uniform force to the cell 152. The lower surface of the cell jig 130 and the cell loaded on the cell jig 130 ( 152 is placed on the top surface of the cell 153 located at the top. In addition, reference numeral 156 is a paper for preventing scratches on the surface of the cell 152 due to friction, between the cell 152 and the cell 152, between the cell 152 and the metal spacer 154, It is inserted between the metal spacer 154 and the metal spacer 154.

Referring to the operation of the liquid crystal injection port sealing press equipment configured as described above is as follows.

The metal spacer 154, the paper 156, the cell 152, the paper 156, and the metal spacer 154 are sequentially disposed in the storage space of the cell jig 130, for example, a 12.1 inch dedicated cell jig 130. Laminate. Thereafter, the cell jig 130 is placed in the pressure chamber 110 to place the cell jig 130 on the upper surface of the base metal 120, and then the cylinder 140 and the cell jig 130 are aligned.

Subsequently, the cylinder 140 is driven to press the metal spacer 154 at a predetermined pressure to control the height of the liquid crystal injection hole to be the same as the height of the cell gap. Thereafter, the cell 152 is irradiated with ultraviolet rays to cure the ultraviolet curable material printed on the liquid crystal injection hole to completely encapsulate the liquid crystal injection hole to prevent the liquid crystal injected between the TFT substrate and the color filter substrate from leaking out.

As such, the size of the base metal 120 may be designed to be larger than the maximum size of the cell 152 that may be injected into the pressurizing chamber 110, and may be used regardless of the size of the cell 152. ) The cell gap is uniform in any area by supporting the entire area and transmitting a uniform force.

As described above, according to the present invention, the base metal is made larger than the maximum size of the cell that can be put in the pressurizing chamber, so that the base metal can be used universally regardless of the size of the cell put in the pressurizing chamber. The replacement of the liquid crystal injection hole encapsulation process time can be prevented.

In addition, by uniformly pressing the entire area of the cell, it is possible to prevent the cell gap failure due to the height difference of the cell gap to improve the reliability of the product.

1 is a cross-sectional view schematically showing a press installation for sealing a liquid crystal injection hole of the present invention.

Claims (2)

A pressurizing chamber in which a cylinder for controlling the cell gap by pressurizing the cell is installed at an upper portion thereof and the process is performed; A base metal installed on a lower surface of the pressure chamber and formed larger than a cell of a maximum size introduced into the pressure chamber; And a cell jig disposed on the base metal and having an accommodation space for accommodating the cell therein. The press for encapsulating a liquid crystal injection hole according to claim 1, wherein the base metal is about 10% larger than the maximum size cell.