KR100669680B1 - Liquid crystal pouring part and sealing method the same of PLCD - Google Patents

Abstract

A liquid crystal inlet and a liquid crystal inlet sealing method of a plastic liquid crystal display device are disclosed. The present invention provides a liquid crystal injection hole of a liquid crystal display device, comprising an expansion portion formed by printing a sealant of an injection hole in a funnel shape, and a liquid crystal penetration guideline formed in a line in the middle of the injection hole with ITO or sealant to guide the penetration position. In the plastic liquid crystal display device, the liquid crystal inlet formed in the morning glory shape and the liquid crystal penetration guideline are formed in the center, and the liquid crystal injection speed is improved and the process is easy when the liquid crystal is injected by vacuum deposition. Since the liquid crystal injection hole is sealed by pressing, defects caused by the reaction between the liquid crystal and the adhesive can be removed, and the liquid crystal cell becomes more reliable at high temperature and humidity.

LCD injection hole, expansion part, liquid crystal penetration guideline, heating crimp head

Description

Liquid crystal pouring part and sealing method the same of PLCD}

1 is a view schematically showing a liquid crystal injection hole of a plastic liquid crystal display device according to the present invention.

2 is a view showing a process of thermocompression bonding the liquid crystal injection hole according to the present invention using a heat compression head.

3 is a view showing a state after cutting the liquid crystal inlet of the plastic liquid crystal display device according to the present invention.

4 is a view schematically showing a liquid crystal injection hole of a conventional plastic liquid crystal display device.

5 is a view showing a method of cutting after sealing the conventional liquid crystal inlet.

<Description of Symbols for Main Parts of Drawings>

2, 4: upper panel and lower panel of plastic liquid crystal display

6: sealant 8: liquid crystal

10: end seal adhesive 12: cutting wheel

22: expansion portion 24: liquid crystal penetrating portion

26: liquid crystal penetration guideline 100,200: liquid crystal inlet                 

300: heating and pressing head

The present invention relates to a liquid crystal injection hole and an injection hole bonding method of a plastic liquid crystal display device, and more particularly, a liquid crystal injection hole for injecting a liquid crystal into a liquid crystal display device employing a plastic substrate and a method of bonding the injection hole after the injection of the liquid crystal is completed. It is about.

Liquid crystal display (LCD: Liquid Crystal Display) has a regular molecular arrangement like liquid crystal along with liquidity of liquid, and has optical anisotropy and changes the molecular arrangement of liquid crystal along the direction of electric field when voltage is applied. It is a flat panel display device that replaces a CRT as a device for displaying a figure, a character or a picture by using a characteristic of a liquid crystal.

Since the liquid crystal display device can adopt a battery power source and is light and small, it is widely used in various portable electronic devices, namely, a notebook computer, a mobile phone, a PDA, and the like.

In the configuration of the liquid crystal display device, a transparent electrode, an insulating film, an alignment layer, and the like are formed on opposite surfaces of the upper and lower substrates, and a liquid crystal injection unit is defined as a sealant. It consists of an attached configuration.

Although glass is generally used as the substrate of the liquid crystal display device, recently, a plastic film is used as the substrate to reduce the thickness and weight due to the tendency of light and thin. On the other hand, the hardness of the glass substrate is different from the manufacturing process in some parts.

4 illustrates a liquid crystal injection hole 100 of a conventional plastic liquid crystal display device.

In the drawing, the sealant 6 is printed between the upper and lower plastic substrates 2 and 4, and the liquid crystal 8 is injected into the liquid crystal injection space defined by the sealant 6, thereby providing an end seal. It is sealed with the agent (10).

When the liquid crystal 8 is injected, it is injected in a vacuum state. Unlike the glass liquid crystal display device, the penetration speed of the liquid crystal 8 is slow, and when the liquid crystal injection hole 100 is expanded to compensate for this, the sealing effect when sealing the end seal There is a disadvantage that is lowered.

When the liquid crystal injection hole 100 is sealed with the end seal 10, a UV curing agent is usually used as in the case of sealing the glass substrate. In addition, in order to commercialize the liquid crystal display device, cutting is performed by the liquid crystal cell unit. In the case of a glass substrate, the glass is scribed with a wheel and then impacted and broken. This is different.

Due to its characteristics, plastics are hardly expected to break due to impacts such as the glass, and plastic is used to cut the entire substrate with wheels.

5 illustrates a method of cutting the substrate 3 after injecting liquid crystal from the conventional plastic liquid crystal display device and sealing the liquid crystal injection hole 100.

As shown in the figure, after the liquid crystal 8 is injected into the substrate 3 cut in units of sticks or cells, the liquid crystal inlet 100 is sealed by using a UV curing agent as the end seal 10. The process of infiltrating and sealing the UV curing agent liquid into the liquid crystal inlet 100 requires considerable attention. That is, when the process is performed by setting the penetration speed and time correctly according to the characteristics of the bonding liquid, the bonding liquid hardens from the surface, so when a process error occurs, the bonding liquid penetrates into the liquid crystal and chemical reaction or staining occurs in the liquid crystal. There is a high possibility of occurrence of a defective rate such as formation.

When cell-cutting the sealed liquid crystal cell, the wheel 12 is used to cut the liquid crystal in the range where the liquid crystal does not flow out along the sealant 6 coating part. In the process of cutting the substrate 3 in this manner, there is a possibility that an impact is applied to the end actual 8 and a small amount of bubbles are generated in the end actual 8 by the impact.

In addition, the liquid crystal display element is required to be highly reliable at high temperature and humidity basically. When the air bubbles are formed in the end chamber 8, when the surrounding environment is hot and humid, By weakening, air penetrates and bubbles are generated in the liquid crystal, or cracks are generated in the end.

The present invention has been made to solve the above-mentioned problems of the prior art is to improve the shape of the liquid crystal injection hole to improve the penetration performance of the liquid crystal, the liquid crystal display element that can improve the reliability by sealing the liquid crystal injection hole by thermocompression bonding It is an object of the present invention to provide a liquid crystal injection hole and a liquid crystal injection hole sealing method.

Liquid crystal injection hole and liquid crystal injection hole sealing method of the liquid crystal display device according to an aspect of the present invention to achieve the above object,

In the liquid crystal injection hole of the liquid crystal display device, the liquid crystal injection hole is formed by printing the sealant of the injection hole in the form of a configuration including a liquid crystal penetration guideline formed in a line in the middle of the injection hole with ITO or sealant to guide the penetration position.

In addition, the method of sealing the liquid crystal injection hole is a step of thermo-compression with a heat compression head within a range that does not contact the sealant defining the injection space of the liquid crystal inside the expansion portion of the liquid crystal injection hole, the heat compression head is instantaneous high temperature And sealing the liquid crystal inlet, and cutting the liquid crystal so that the liquid crystal does not flow out of the portion sealed by the thermocompression bonding.

By forming the liquid crystal inlet of the plastic liquid crystal display device and sealing the liquid crystal inlet as described above, the liquid crystal injection speed is improved and the process is easy when the liquid crystal is injected by vacuum deposition, and the liquid crystal cell is sealed at a high temperature. Reliability is improved with humidity.

The configuration of the present invention will be described in more detail with reference to the accompanying drawings. For reference, prior to the description of the present invention will be referred to the same reference numerals as for the parts corresponding to the conventional drawings.

1 is a view schematically showing a liquid crystal injection hole 200 of a plastic liquid crystal display device according to the present invention.                     

In the figure, the liquid crystal injection hole 200 according to the present invention is composed of a liquid crystal penetrating portion 24 and a liquid crystal penetrating guide line 26 extending in a straight line and a straight line, such as the cross section of the funnel. The line forming the liquid crystal injection hole 200 is formed by being printed while the sealant 6 defining the liquid crystal injection space extends, and the liquid crystal penetration guide line 26 is drawn across the center of the extension portion 22.

The extension part 22 is formed by extending the radial sealant 6 about 2 mm and printing it.

The liquid crystal penetration guide line 26 is to increase the amount of liquid crystal penetration in the initial stage of vacuum deposition, and determines the injection direction of the liquid crystal 8 so that the liquid crystal 8 flows along the guide line 26 to be injected more smoothly. It would be.

The liquid crystal penetration guide line 26 may be patterned by setting a position when patterning the transparent electrode 28 on the upper and lower panels without going through a separate process, or printing a predetermined amount of the sealant 6 on a line in the sealant printing process. To form.

The liquid crystal penetration guide line 26 prevents penetration into the cutting line after sealing the liquid crystal injection hole 200 to ensure reliability when sealing the liquid crystal injection hole 200.

As described above, a method of designing the liquid crystal injection hole 200 and injecting the liquid crystal 8 and then sealing the liquid crystal injection hole 200 will be described with reference to FIG. 2.

Referring to FIG. 2, when the liquid crystal injection hole 200 is sealed after all of the liquid crystals 8 are injected, a thermocompression encapsulation method for pressing the heat compression head 300 is employed. At this time, the heat-compression head 300 is pressurized carefully so as not to contact or heat deformation of the substantially rectangular sealant defining the liquid crystal injection space. If the heat-compression head 300 is in contact with the sealant 6 other than the liquid crystal injection hole 200 or subjected to thermal deformation, deformation of the cell gap is caused.

While pressing the liquid crystal injection hole 200 while pressing the liquid crystal injection hole 200 at a high temperature, the upper panel 2 and the lower panel 4 are adhered and sealed. As described above, since the heat-compression head 300 can be adjusted to maintain a constant cell gap before adhering the upper and lower panels 2 and 4, the disparity of the cell gap can be eliminated.

That is, the method of sealing the liquid crystal injection hole 200 in the present invention is heated in a range that does not contact the sealant 6 that defines the injection space of the liquid crystal 8 into the expansion portion 22 of the liquid crystal injection hole 200. Thermocompression bonding with the crimping head 300, sealing the liquid crystal injection hole 200 at an instantaneous high temperature with the thermocompression head 300, and the liquid crystal 8 is not leaked to the sealed portion by the thermocompression bonding. It characterized in that it comprises a step of cutting to avoid.

FIG. 3 is a view illustrating a liquid crystal injection hole cut by thermocompression bonding with the heat compression head 300.

As shown in the figure, the liquid crystal injection hole 200 may be pressed into the heat compression head 300, and then the liquid crystal penetrating portion 24 may be cut to obtain a desired product size.

As described above, when the liquid crystal injection hole 200 of the plastic liquid crystal display device extends the sealant than conventionally, the expansion portion 22 is formed, and the liquid crystal penetration guide line 26 is formed in the center of the expansion portion 22. 8) can increase the initial penetration amount and facilitate the process work, and the process TACT TIME is reduced and reliability is maintained by sealing the liquid crystal injection hole 200 by high temperature instantaneous thermocompression while maintaining the cell gap with the heat-compression head 300. Can be improved.

In addition, since a chemical adhesive such as a UV curing agent is not used when sealing the liquid crystal injection hole 200, a disadvantage of causing a chemical reaction with the liquid crystal material 8 may be solved.

Forming a morning glory-shaped liquid crystal inlet and a liquid crystal penetration guideline in a plastic liquid crystal display device, the liquid crystal injection speed is improved and the process is easy when the liquid crystal is injected by vacuum deposition, and the thermal compression head is pressed. Since the liquid crystal inlet is sealed, defects caused by the reaction between the liquid crystal and the adhesive can be eliminated, and the liquid crystal cell becomes more reliable at high temperature and humidity.

Claims (6)

An extension formed by extending a sealant defining an injection space of the liquid crystal; And Liquid crystal inlet of the plastic liquid crystal display device comprising a; liquid crystal penetration guide line disposed between the expansion portion, to guide the liquid crystal penetration direction. The liquid crystal injection hole of claim 1, wherein the liquid crystal penetration guideline is a transparent electrode. The liquid crystal inlet of claim 1, wherein the liquid crystal penetration guideline is a sealant. The liquid crystal inlet of claim 1, wherein the liquid crystal penetration guideline is formed at the center of the enlarged portion. Thermo-compressing the upper and lower panels with a heat-compression head within a range not in contact with a sealant defining an injection space of the liquid crystal inside the expansion portion of the liquid-crystal injection hole, and the heat-compression head seals the liquid crystal injection hole at an instantaneous high temperature And cutting the liquid crystal so that the liquid crystal does not flow out from the portion sealed by the thermocompression bonding. The liquid crystal inlet sealing method of claim 5, wherein the heating and pressing head is adjusted to maintain the cell gap of the liquid crystal cell when the upper and lower panels are pressed.

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