KR970000358B1 - Liquid crystal injecting method and its device - Google Patents

Abstract

A method and a device for filling a liquid crystal into a cell by using a capillary phenomenon. The method has the step of raising the liquid crystal(L) upward and making the raised liquid crystal(L) contact with the inlet(I) of the cell(C). The device for the same has a capillary block member(1) having a capillary groove(1a) along which the liquid crystal rises. The block member(1) is immersed a lower portion thereof into the liquid crystal(L) in a reservoir(R) and extend over the liquid crystal(L). The top portion of the capillary groove(1a) makes a point contact with the inlet(I) of the cell(C) thereby the raised portion of the liquid crystal(L) flowing into the cell(C).

Description

Liquid crystal injection method and device

1 is a schematic cross-sectional view showing a conventional liquid crystal injection device.

2 is a schematic cross-sectional view for explaining the principle of the liquid crystal injection device according to the present invention.

FIG. 3 is a side view showing a preferred embodiment of the liquid crystal injection device shown in FIG.

4 is a cross-sectional view showing another embodiment of the device of the present invention.

FIG. 5 is a side view showing a preferred embodiment of the apparatus of FIG.

6 is a side view showing another embodiment of the device of the present invention.

* Explanation of symbols for main parts of the drawings

C: Cell 1: Injection Block

I: injection port 2,2: injection bar

L: Liquid Crystal 1a, 2a, 2a: Injection Groove

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to the manufacture of liquid crystal displays (LCDs), and more particularly to a method of injecting a liquid crystal into an LCD and an injection apparatus suitable for the practice of the method.

LCDs, which use optical properties such that liquid crystal materials are rearranged under an electric field to change their light transmittance and refractive index, are used for displaying images. The display device has a low light and small display device such as low driving potential and low power consumption. It is possible to configure and widely used. The use range of these LCDs is very wide, ranging from wristwatches and small indicators to the development of large wall-mounted TVs, and LCDs of various sizes and sizes are manufactured.

In general, the manufacturing process of the LCD is formed by forming a transparent electrode pattern and an alignment layer on a glass or synthetic resin substrate, and then bonding both substrates to form a liquid crystal in a cavity formed therebetween. It is composed by injecting and sealing. The injection of such liquid crystal is generally made by a vacuum injection method as shown in FIG.

In FIG. 1, the liquid crystal container R containing the liquid crystal L is located in the vacuum chamber V, and a cell C in which the liquid crystal L is injected is positioned. In this state, the vacuum pump P is operated to exhaust the inside of the vacuum chamber V to a predetermined degree of vacuum, and then the injection port I of the cell C is locked to the lower surface of the liquid crystal L. When the vacuum chamber V is leaked to release the vacuum in the vacuum chamber V, the liquid crystal L is injected into the cavity K by the negative pressure in the cavity K of the cell C. Will be.

Such a method has an advantage that the liquid crystal (L) can be injected into a large amount of cells (C) at the same time, but when the size of the cell (C) into which the liquid crystal (L) is injected becomes small, the liquid crystal (L) is contaminated. It will cause various problems. In particular, in the case of a small LCD used as an wrist watch or a small indicator, such a conventional method cannot inject an appropriate amount of liquid crystal (L). In addition, since the cell (C) is directly contained in the liquid crystal (L), not only a large amount of liquid crystal (L) is required but also foreign matter attached to the cell (C) is mixed with the liquid crystal (L) has a problem of contamination.

In view of such a conventional problem, the present invention can inject an appropriate amount of liquid crystal even with a small amount of liquid crystal, and there is no problem of cell contamination or liquid crystal glossiness due to unnecessary liquid crystal adhesion, and thus, particularly for liquid crystal injection of a small LCD. It is an object to provide a suitable liquid crystal injection method.

Another object of the present invention is to provide a liquid crystal injection device suitable for implementing the above-described method of the present invention.

A liquid crystal injection method for achieving the object of the present invention is a method of injecting a liquid crystal into the cell at the negative pressure of the liquid crystal display cell exhausted by vacuum, by raising the liquid crystal from the liquid level of the liquid crystal to the capillary phenomenon, the liquid crystal It is characterized in that the liquid crystal is injected into the cavity of the cell by point contact with the injection hole of.

A liquid crystal injection device suitable for implementing the method of the present invention includes a vacuum chamber capable of evacuating with a vacuum and a liquid crystal container installed in the vacuum chamber, wherein the liquid crystal is injected into the cavity of the cell, the lower part of which is contained under the liquid level of the liquid crystal of the liquid crystal container. And an injection block having an upper portion protruding onto the liquid level of the liquid crystal and having an injection groove having a predetermined size in contact with an injection hole of a cell extending from the liquid level below the liquid level to the liquid level around the liquid crystal.

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

First, in FIG. 2, the liquid crystal injection device according to the present invention includes an injection block 1 in which an upper portion thereof protrudes onto the liquid level of the liquid crystal L in the liquid crystal container R in which the liquid crystal L is accommodated. An injection groove 1a having a predetermined depth and width is formed along the outer circumference of the injection block 1 so that the liquid crystal L under the liquid surface rises along the injection groove 1a by capillary action, thereby causing the injection groove 1a. The surface of the liquid crystal L, which is uniformly filled in and filled in the injection groove 1a by the surface tension of the liquid crystal L, is indicated by a dotted line in FIG. 2 (particularly seen in the enlarged circle of FIG. 3). Like it protrudes to the outside of the injection groove (1a).

The liquid crystal L is injected into the cavity K of the cell C by contacting the cell C with the liquid crystal L convexly protruding outside the injection groove 1a. It is preferable that the injection groove 1a of the injection block 1 and the injection hole I of the cell C are in point contact so that the liquid crystal L is not attached to an unnecessary portion other than I). To this end, the injection block 1 is configured such that the upper surface thereof is formed in a curved surface so that the lower end of the cell C comes into tangential contact with its apex, so that only the injection hole I is in point contact with the liquid crystal L. . Preferably the injection block 1 has a cut circle or elliptical cross section.

The present invention injection device having such a configuration is injected into the vacuum chamber as in the prior art to inject the liquid crystal by the hole injection method. That is, as shown in FIG. 3, the plurality of cells C are aligned and supported on a tray (not shown) with their injection holes I downward, respectively, and the liquid crystal L The components of the present invention having an injection block (1) formed with a plurality of injection grooves (1a) which are immersed in a lower portion thereof and continuous therefrom are installed in the chamber. After evacuating the vacuum chamber to a predetermined vacuum, the injection port I of each cell C is brought into contact with the corresponding injection groove 1a of the injection block 1 of the present invention, and the vacuum chamber is leaked. The liquid crystal 1 is sucked into the cell C to inject. At this time, the force acting on the liquid crystal (L) in the injection groove (1a) has the surface tension to raise the liquid crystal (L), the gravity to lower, and the adhesive force to prevent the rise and fall. Since the surface tension of the liquid crystal L and the adhesion force between the injection groove 1a of the liquid crystal L and the gravity are balanced, the amount of the liquid crystal L that can be injected is constant according to the size of the injection groove 1a. A constant amount of liquid crystal L is injected into (C) at all times. Therefore, the size of the injection groove 1a may be set differently according to the amount of the liquid crystal L to be injected, that is, the size of the cell C.

On the other hand, if the size of the injection groove 1a is too small, the adhesion and gravity of the liquid crystal L become considerably larger than the surface tension, so that the liquid crystal L cannot be smoothly raised even by the capillary phenomenon of the injection groove 1a. . Therefore, even in the embodiments of FIGS. 2 and 3, it may be difficult to inject a uniform amount of liquid crystal L into a very small cell.

Accordingly, in the embodiment of FIG. 4, the injection hole I of the cell C is inserted into the injection groove 2a formed in the injection bar 2 by contacting a cylindrical injection bar 2 on the injection block 1. ) Is injected to inject the liquid crystal (L). At this time, the size of the injection groove 2a of the injection bar 2 is preferably configured to be smaller than the size of the injection groove 1a of the injection block 1, in particular, as shown in FIG. When the injection groove 1a of the injection block 1 raises the liquid crystal L on the liquid level of the liquid crystal, the injection groove 2a of the injection bar 2 in contact with the injection groove 1a is relatively low. By raising the liquid level, even a very small cell C can be smoothly injected with liquid crystal. That is, by lowering the injection groove, the liquid level capable of raising the liquid crystal L is lowered, so that the injection groove 1a of the relatively large injection block 1 serves as a pump to raise the liquid crystal L in two stages. Will be.

On the other hand, when the size of the cell becomes smaller, that is, it is difficult to sufficiently raise the liquid crystal L even with the small injection grooves 2a formed in the injection bar 2, the embodiment as shown in FIG. It can also be configured. In the embodiment of Fig. 6, the injection groove 2a 'of the injection bar 2' is formed in a screw shape so that it can be rotated by a predetermined angle, preferably 180 ° by a driving means not shown. It is. In this embodiment, just before the leak of the vacuum chamber, in the state where the injection groove 2a 'of the injection bar 2' is in contact with the injection groove 1a of the injection block 1 and the liquid crystal L is attached by a predetermined level. Rotate the injection bar (2´) to 180 °. Then, the liquid crystal attached to the lower portion of the injection groove 2a 'of the injection bar 2' comes to the upper side of the injection bar 2 'and in this state contacts the injection hole I of the cell C to leak. If a small amount of liquid crystal (L) is injected into the small cell (C).

As described above, in the invention, in consideration of the balance between the surface tension of the liquid crystal and the gravity and adhesion, the capillary phenomenon caused by the surface tension can be used to inject a uniform amount of liquid crystal even in a very small cell. As a result, LCD defects due to inadequate liquid crystal injection amount are prevented, thereby significantly improving productivity and quality of the LCD. In addition, the problem that the liquid crystal adheres to the cell surface and is contaminated, the problem that the foreign matter of the cell mixed in the liquid crystal can be prevented fundamentally.

Claims (7)

A method of injecting liquid crystal into a cell at a negative pressure of a liquid crystal display cell exhausted by vacuum, wherein the liquid crystal is raised from a liquid level of the liquid crystal to a capillary phenomenon, and the liquid crystal is brought into point contact with an injection hole of the cell. And injecting the liquid crystal into the cavity of the cell. An apparatus for injecting liquid crystal into a cavity of a cell, comprising a vacuum chamber capable of evacuating to a vacuum and a liquid crystal container installed in the vacuum chamber, wherein the lower portion is contained under the liquid level of the liquid crystal L of the liquid crystal container R, and the upper portion is An injection groove 1a of a predetermined size which protrudes onto the liquid level of the liquid crystal L, extends from below the liquid level of the liquid crystal L to the liquid level, and contacts the injection hole 1 of the cell C Liquid crystal injection device comprising a formed injection block (I). According to claim 2, wherein the upper surface of the injection block (1) is formed in a curved surface, the injection hole (I) of the cell (C) is in contact with the injection groove (1a) of the upper injection block 1 Liquid crystal injection device characterized in that. According to claim 2, Between the injection block 1 and the cell (C), the injection groove corresponding to the injection groove (1a) and the injection port (I) of the cell (C) of the injection block (1) A liquid crystal injection device, characterized in that an injection bar (2, 2 ') is formed around the (2a, 2a'). 5. The liquid crystal injection apparatus according to claim 4, wherein the injection groove (2a ') of the injection bar (2') is formed spirally. The love injection device according to any one of claims 4 to 5, wherein the injection bars (2, 2 ') are rotatable by a predetermined angle. The cell C according to any one of claims 2 to 5, wherein the cell C is provided in plural and the injection grooves 1a, 2a, 2a 'are provided in plural to correspond to the cells C, respectively. Liquid crystal injection device, characterized in that.