KR100493377B1 - Appratus for removing electro static and method for removing electro static of liquid crystal display device using the same - Google Patents

Abstract

An object of the present invention is to provide an antistatic device capable of improving the antistatic ability of an antistatic object by allowing the atmosphere in the air to be always in a neutral state during electrostatic discharge, and a method of eliminating the liquid crystal display device using the same. The device is arranged between an ionizer, which is generated by repeating positive and negative ions periodically, an antistatic object to which incoming static electricity is to be removed, and between the ionizer and the antistatic object, one end of which is connected to ground And a conductive bar for bypassing the surplus ions remaining after the static electricity of the static elimination object is removed. The method of eliminating the liquid crystal display using the antistatic device as described above comprises the steps of: bonding a TFT substrate and a color filter substrate; A step of forming a liquid crystal panel by injecting liquid crystal between the substrate and the color filter substrate, and periodically (+) ions and (-) Removing the static electricity flowing into the substrate forming the liquid crystal panel by loading the liquid crystal panel under the repeatedly generated ionizer, and placing a conductive bar between the ionizer and the liquid crystal panel to prevent static electricity flowing into the substrate. And removing the excess ions generated by the ionizer remaining after the removal to the ground terminal.

Description

Antistatic device and antistatic method of liquid crystal display device using same {APPRATUS FOR REMOVING ELECTRO STATIC AND METHOD FOR REMOVING ELECTRO STATIC OF LIQUID CRYSTAL DISPLAY DEVICE USING THE SAME}

The present invention relates to an antistatic device for improving the static elimination efficiency of the antistatic object and a method of eliminating the liquid crystal display device using the same.

In general, a liquid crystal display device displays an image by injecting a liquid crystal between two substrates, and adjusting an amount of light transmission by adjusting an intensity of an electric field applied to the liquid crystal.

Such liquid crystal displays commonly generate static electricity in almost all processes through deposition, etching, and liquid crystal cell processes on a transparent glass substrate. It acts as a factor to reduce the defects of the product and the resulting yield, such as device breakdown and dielectric breakdown caused by (Electro Stactic Damage).

Since these ESD phenomena are also numerous, it is difficult to quantify or classify them correctly.However, efforts to prevent and disperse static electricity by using a protection circuit or insertion of a diode or a shorting bar are continued. have.

If the static electricity is not removed, the yield of the product is greatly reduced. In particular, the quantity and sub inspection of the panel must be carefully prepared for the static electricity.

That is, when the panel is lit and visually inspected in the state where liquid crystal injection is completed, the inspector inspects the panels one by one to determine whether they are positive or negative. If the static electricity is locally charged on the surface of the panel, the liquid crystal is turned on. When the charged part looks like a defect. In other words, since the static electricity automatically disappears over time, the liquid crystal panel is actually a good product. However, since the stain is generated by the static electricity, it can be mistaken as if it is a bad product. It is.

In view of this, when the amount or negative judgment of the liquid crystal panel is performed, the inspector may judge that the stain is caused by a simple static electricity, even though the stain is caused by other defects in the spot where the stain is generated, not by a simple static electricity stain. This may result in judging the liquid crystal panel which is actually defective as good.

As a result, failure to deal fully with static electricity can have a major impact on product yield, and various approaches are being sought to remove static electricity.

In general, as shown in Fig. 1, a structure in which a common short line 1 is provided outside the TFT array is adopted.

That is, the end of each data bus line 3 is shorted by the common short line 1, and each gate bus line 5 is also configured such that the end thereof is shorted by the common short line 1. do. The common short line 1 may be electrically connected to each other to prevent a short between bus lines due to static electricity. At this time, after the manufacturing process of the liquid crystal display device is completed, the common short line 1 is removed by cutting the substrate 10 along the cutting line 7.

On the other hand, unlike the antistatic structure of the liquid crystal display device, the static electricity flowing into the antistatic object may be eliminated by direct charging of ions generated in the ionizer.

There are various types of ionizers called ionizers, depending on the application range. Among them, an AC-driven ionizer mainly used in liquid crystal displays will be described as an example.

As shown in FIG. 2A, the ionizer 21 to which nitrogen (N ₂ ) gas is supplied is provided with a plurality of discharge needles 21a, and positive and negative ions are passed through the discharge needles 21a. The ions are generated alternately. Normally, the time interval between (+) and (-) ions is about 1/60 second, and nitrogen gas charged to (+) is generated in 1/60 seconds, and then charged to (-) in 1/60 seconds. Nitrogen gas is generated.

As described above, since the positive and negative ions are periodically generated, the amount of the positive and negative ions is the same when viewed from the outside, and thus, between the ionizer 21 and the antistatic object 23. The atmosphere as a whole becomes neutral.

For example, in the case where a positive ion is charged to the antistatic object 23 locally, as shown in FIG. 2B, the positive ion generated by the ionizer 21 is positively generated using the ionizer. The ions are pushed out by the positive ions of the antistatic object 23, while the negative ions are attracted to the surface of the antistatic object 23 and move toward the surface of the antistatic object 23 and are charged with the positive ions 23. By neutralization, the static electricity (charged (+) ions) charged on the antistatic object 23 is removed.

In this way, the static electricity flowing into the liquid crystal display device can be removed. The liquid crystal panel serving as the antistatic object is moved to the lower portion of the ionizer to remove the static electricity flowing into the liquid crystal panel.

If negative ions are charged to the liquid crystal panel, the ions generated in the ionizer 21 will be neutralized with the positive ions, and at this moment, the atmosphere between the liquid crystal panel and the ionizer 21 will be neutralized. The ion will be in more state, i.e., incomplete neutral state. On the other hand, if (+) ions are charged to the liquid crystal panel, among the ions generated in the ionizer 21 will be neutralized with the negative (-) ions, the atmosphere between the liquid crystal panel and the ionizer 21 at this moment ( The more ions will be in the state.

In general, in the liquid crystal display, static electricity flows in the process of forming various patterns on the glass substrate, or a lot of static electricity flows in the process of scribing and breaking the glass substrate in units of cells.

Therefore, conventionally, after forming various patterns on the glass substrate and before the scribing process, the glass substrate is placed under the ionizer to remove static electricity generated in various manufacturing processes, or to scribe and break After the process is completed, the liquid crystal panel (Panel) separated by the cell unit is placed under the ionizer to remove the static electricity introduced into the panel.

However, the antistatic structure of the conventional liquid crystal display device has the following problems.

At the moment of removing the positively charged ions locally on the liquid crystal panel (or glass substrate) by using the ionizer, the amount of negative ions moved to the antistatic object is eliminated in the air. The amount of positive ions increases. This is not a complete neutral state, and the (+) ions are automatically destroyed after a time, but a long time is required to automatically disappear.

In addition, since the ionizer generates ions in the upper portion of the liquid crystal panel, the static electricity charged on the rear surface of the liquid crystal panel cannot be removed.

The present invention has been made to solve the above-mentioned problems of the prior art, the antistatic device that can improve the antistatic ability of the antistatic object by maintaining the atmosphere in the air at the time of static neutralization and liquid crystal display using the same It is an object of the present invention to provide a method for static elimination of devices.

The antistatic device of the present invention for achieving the above object is an ionizer which is generated by repeating (+) ions and (-) ions periodically, an antistatic object to be introduced static electricity, and the ionizer and the antistatic object And a conductive bar disposed between the one end and the one end connected to the ground to bypass the surplus ions remaining after removing the static electricity of the static electricity elimination object. Bonding the color filter substrate, forming a liquid crystal panel by injecting liquid crystal between the TFT substrate and the color filter substrate, and periodically under the ionizer where positive and negative ions are repeatedly generated. Loading the liquid crystal panel to remove static electricity introduced into the substrate constituting the liquid crystal panel, and between the ionizer and the liquid crystal panel By placing the conductive bar and characterized in that comprising the step of the by-pass the excess ions to the ground terminal occurs in the rest of the ionizer to remove the static electricity flows to the substrate.

Such a static elimination device of the present invention uses a grounding bar so that the atmosphere in the air temporarily has a polarity when the static electricity elimination object is discharged by the ionizer so as to be in a neutral state within a short time.

Hereinafter, the antistatic device and the antistatic method of the liquid crystal display device using the same according to the present invention will be described in detail with reference to the accompanying drawings.

3 is a schematic diagram illustrating a static eliminator according to the present invention.

As shown in FIG. 3, the ionizer 21 is provided with a discharge needle 21a to periodically output positive and negative ions, and an antistatic object 23 into which static electricity flows, It comprises a conductive bar 25 formed between the ionizer 21 and the antistatic object 23.

Here, the conductive bar 25 is to remove the excess ions existing between the ionizer 21 and the antistatic object 23 in the process of removing the static electricity charged on the antistatic object 23, the ionizer ( It is for quickly making the atmosphere between the 21 and the antistatic object 23 to a neutral state, the end of which is connected to the ground (Ground).

The ionizer 21 generates ionized nitrogen (N ₂ ) gas, which generates a positively charged nitrogen gas for 1/60 seconds, and then a negatively charged nitrogen gas for 1/60 seconds. Gas is generated.

As shown in the figure, assuming that (+) ions are locally charged to the antistatic object 23, the (+) ions generated in the ionizer 21 are positively affected by repulsive force. The negative ions are pushed out by the neutralizing object 23 and neutralized with the locally charged positive ions.

At this time, in the space between the antistatic object 23 and the ionizer 21, there are surplus (+) ions corresponding to the negative (-) ions that are released to react with the positive ions of the antistatic object 23. In addition, the excess (+) ions do not exist as a complete neutral state, it becomes (+) polarity.

However, the surplus (+) ions are eventually connected to the ground and charged to the surface of the conductive bar 25 disposed between the antistatic object 23 and the ionizer 21 to exit toward the ground eventually, In the space between the antistatic object 23 and the ionizer 21, (+) ions and (-) ions have the same neutral state. In this case, the ionizer 21 and the conductive bar 25 is shown when the upper portion of the antistatic object 23, the ionizer 21 and the conductive bar 25 is the antistatic object 23 of the It may be located at the bottom. As a result, since the ionizer 21 and the conductive bar 25 can be freely moved up and down / left and right of the static elimination object 23, the static electricity charged on the upper and lower portions of the static elimination object 23 can be more easily removed. .

Meanwhile, the conductive bar 25 may be formed in a bar shape as shown in FIG. 3, or may be formed in a net shape as shown in FIG. 4, which is not a bar shape. Any form may be used as long as the space between the static elimination object 23 and the ionizer 21 can be quickly made into a neutral state.

Referring to FIG. 5, a method of eliminating the liquid crystal display using the antistatic device of the present invention will be described below.

First, a liquid crystal display device includes a TFT substrate 41 in which a TFT array is implemented on a glass substrate, a color filter substrate 41a in which a color filter pattern is implemented, and a gap between the TFT substrate 41 and the color filter substrate 41a. It is made of a sealed liquid crystal layer 43.

A pixel region is defined by crossing a plurality of scan lines and a plurality of data lines on the TFT substrate 41, and a thin film transistor (TFT: Thin) is formed at an intersection of each of the data lines and the scan lines. Film Transistor) is disposed.

The thin film transistor includes a gate electrode extending from a scan line, a source electrode and a drain electrode extending from the data line, and a pixel electrode formed of a transparent conductive material and electrically connected to the drain electrode in the pixel region.

Meanwhile, a black matrix pattern is formed on the color filter substrate 41a to prevent light from being transmitted to a region other than the pixel electrode formed on the TFT substrate, and together with the pixel electrode, an electric field is applied to the liquid crystal layer 43. The common electrode is formed.

The TFT substrate 41 and the color filter substrate 41a are bonded together by a sealant, and a liquid crystal is injected between the two substrates.

Here, in manufacturing the TFT substrate 41, a lot of static electricity is introduced in the process of forming a plurality of patterns, such as the scan line, data line and various electrodes of the thin film transistor, and similarly the process of manufacturing the color filter substrate 41a Even in the presence of a lot of static electricity.

In addition, after forming a plurality of patterns on the glass substrate as described above, the static electricity due to friction is charged to the substrate of the cell unit in the process of scribing and breaking the cell unit.

Therefore, in order to remove such static electricity, the liquid crystal panel cut in units of cells is loaded under the ionizer 21.

That is, the liquid crystal panel periodically generates positive (+) ions and negative (-) ions, and the end thereof is disposed on a static elimination device provided with a conductive bar 25 connected to the ground, that is, the lower side of the conductive bar 25. Move it. In this case, if the static electricity is locally introduced into the liquid crystal panel, the static electricity introduced into the liquid crystal panel may be removed by the above-described process, and the atmosphere between the ionizer 21 and the liquid crystal panel may be quickly neutralized. You can make

The ability to make the atmosphere between the ionizer 21 and the liquid crystal panel in a neutral state within a short time means that the antistatic capability can be improved by that much. Therefore, when such an antistatic process is performed for each glass substrate, This means that the time required for static elimination can be shortened by that much.

As described above, the antistatic device of the present invention and the antistatic method of the liquid crystal display device using the same have the following effects.

The atmosphere between the ionizer and the antistatic object can be made into a completely neutral state with no polarity, and the time for making it into a neutral state can be shortened by that much.

That is, by forming a conductive bar connected to the ground terminal between the ionizer and the antistatic object, the excess ions generated during the static elimination are bypassed toward the ground terminal through the conductive bar to completely neutralize the atmosphere between the ionizer and the antistatic object. Can be made with

The liquid crystal display that removes static electricity introduced through such a process goes through various tests. Since the test is performed in the state of completely removing static electricity, there is no fear of error of inspection due to the remaining static electricity. There is no fear to judge that the product is defective, thereby improving the yield of the product.

1 is a plan view for explaining a method of eliminating the liquid crystal display device using a conventional shorting bar

2A and 2B are diagrams for explaining an antistatic device using a conventional ionizer.

3 is a block diagram of an antistatic device of the present invention

4 is a view showing a conductive bar of the mesh type according to the antistatic device of the present invention

5 is a view for explaining a method of eliminating the liquid crystal display device using the antistatic device according to the present invention.

Explanation of symbols for main parts of the drawings

21: ionizer 21a: discharge needle

23: antistatic object 25: conductive bar

41: TFT substrate 41a: color filter substrate

43: liquid crystal layer

Claims (5)

Ionizer which is generated by repeating (+) ion and (-) ion periodically, Antistatic objects to be removed, And a conductive bar disposed between the ionizer and the antistatic object in a non-contact type with the antistatic object and having one end connected to the ground to bypass surplus ions remaining after removing the static electricity of the antistatic object. Antistatic device. The antistatic device of claim 1, wherein the conductive bar comprises a mesh. The antistatic device of claim 1, wherein the conductive bar is freely movable above and below the antistatic object. According to claim 1, wherein the excess ions of the amount of (-) ions charged in the (+) polar static electricity of the ions generated in the ionizer to remove the (+) polar static electricity flowing into the antistatic object Antistatic device, characterized in that the corresponding (+) ion. Bonding the TFT substrate and the color filter substrate together; Forming a liquid crystal panel by injecting liquid crystal between the TFT substrate and the color filter substrate; Loading the liquid crystal panel under the ionizer where the positive and negative ions are periodically generated to remove static electricity introduced into the substrate constituting the liquid crystal panel; And placing a conductive bar between the ionizer and the liquid crystal panel to remove the static electricity introduced into the substrate, thereby bypassing the surplus ions generated in the ionizer to the ground terminal. Method of elimination.