JPH05241190A - Liquid crystal display device - Google Patents

Abstract

PURPOSE:To repair the shorting defect between the display electrodes and auxiliary capacity electrodes of the liquid crystal display panel to be used for a liquid crystal projector. CONSTITUTION:The display electrodes 9 and the auxiliary capacity electrodes 10 electrically separated from the electrodes 9 are formed on an insulating substrate 1. These auxiliary capacity electrodes 10 are formed to an annular shape and notched parts 9A are provided in the display electrodes 9 to prevent the display electrodes 9 and the auxiliary capacity electrodes 10 from being superposed in the notched parts 9A.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a liquid crystal display device, and more particularly to a liquid crystal display device used for a liquid crystal projector.

[0002]

2. Description of the Related Art In recent years, liquid crystal projectors have become available with the increase in screen display. In such a projector, when white light generated from a light source is incident on a dichroic prism via a condenser lens, it is divided into red, green, and blue, and a part of each color component, for example, red and blue, is reflected by a total reflection mirror. After that, the red, green, and blue components, which are respectively modulated by the liquid crystal display panel as a change in transmittance, are further combined by a dichroic mirror and projected on a screen by a projection lens.

As a liquid crystal projector using a liquid crystal display panel, there is Japanese Patent Laid-Open No. 61-150487, and its description is omitted here. In the liquid crystal projector described above, it is necessary to increase the number of pixels of each liquid crystal display panel in order to achieve high image quality. For example, NTSC full line display can be performed by using a panel of vertical 480 × horizontal 720. . However, as the number of pixels increases, T
FT (thin film transistor) has also increased, and there has been a problem that the yield of display panels is reduced.

In order to solve such a problem, a method is generally adopted in which, for example, two TFT elements are formed on one pixel electrode and the TFT element is operated even if any one of them becomes defective.

[0005]

However, even if two TFT elements are provided on the electrode of one pixel as described above, for example, a pinhole is formed by dust or the like during the gate insulating film forming step, It is difficult to completely prevent the occurrence of display defects due to a short circuit between the auxiliary capacitance metal and the pixel electrode.

In this case, since the liquid crystal display panel for the projector is displayed in the normally white mode, the defective pixel electrode becomes a white dot on the screen although the display electrode and the auxiliary capacitance electrode are short-circuited. Since it is displayed, there is a problem that the display quality on the screen is significantly deteriorated. Further, if such defects occur at a plurality of places, there is a problem that the liquid crystal display panel cannot be used as a projector.

Further, this problem may frequently occur with an increase in the number of pixels, which has been a major obstacle in realizing a large-sized display panel. The present invention has been made in view of the above-mentioned problems, and an object of the present invention is to enable reproduction even when the display electrode and the auxiliary capacitance electrode are short-circuited and cannot be used in normally white mode display. An object of the present invention is to provide a liquid crystal display device that improves the yield.

[0008]

A liquid crystal display device according to the present invention includes a display electrode formed on an insulating substrate, a switching element connected to the display electrode, and a portion of the display electrode that is overlapped and insulated. An auxiliary capacitance electrode formed via a layer, the auxiliary capacitance electrode is formed in a ring shape, and the auxiliary capacitance electrode and the display electrode overlap each other at least at two or more portions of the overlapping region. It is characterized by the existence of areas that do not exist. Further, a liquid crystal display device according to the present invention includes a display electrode formed on an insulating substrate and provided with at least two cutout portions around the display electrode, a switching element connected to the display electrode, and The auxiliary capacitance electrode is formed to overlap a part of the display electrode via an insulating layer, the auxiliary capacitance electrode is formed in a ring shape in a peripheral region of the display electrode, and the display electrode and the auxiliary capacitance are formed in the cutout portion. It is characterized in that it does not overlap the electrodes.

[0009]

In the liquid crystal display device configured as described above, even when the display electrode and the auxiliary capacitance electrode are short-circuited, the auxiliary capacitance electrode in the area where these electrodes do not overlap is broken at two places. This makes it possible to electrically isolate the short portion. As a result, even if the display electrode and the auxiliary capacitance electrode are short-circuited, the display pixel itself can be reproduced.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below based on the embodiments shown in FIGS. FIG. 1 is an enlarged plan view of an essential part showing one pixel of the display panel of the present invention, and FIG. 2 is ZZ of FIG.
It is a cross-sectional view, (1) is an insulating substrate such as soda glass or borosilicate glass, (2) is a gate electrode made of Cr, Cr + Au, Mo, etc., (3) is an insulating protective film such as SiNx, ( 4) is a semiconductor layer composed of amorphous silicon, Te, polysilicon, Cdse, etc., (5)
Is passivation for protecting the surface of the semiconductor layer (4),
(6) and (7) are drain electrodes and source electrodes formed of Al, Mo and ITO, (8) is a drain electrode (6),
N ⁺ a-Si for making ohmic contact between the source electrode (7) and the semiconductor layer (4), (9) a transparent display electrode formed of ITO or the like, and (10) an auxiliary capacitance electrode. Showing.

The respective display electrodes (9) are arranged corresponding to a color filter (not shown). The gate electrodes (2) are arranged between the rows of the display electrodes (9) and the drain electrodes (6) are arranged between the columns. Are formed in such a manner that the display electrodes (9) are partitioned from each other, and the gate electrode (2), the insulating protective film (3), the semiconductor layer (4), the drain electrode (6), and the source electrode are formed at one corner of the intersection of the two. A plurality of thin film transistors (11) composed of (7) and the like are formed so as to connect with the display electrodes (9). In this embodiment, the two thin film transistors (11) are formed so as to be adjacent to each other, but this is to drive the display electrode (9) even when one of the thin film transistors (11) becomes defective. It is a spare for doing.

However, even if a plurality of thin film transistors (11) are formed, if each thin film transistor (11) itself or the display electrode (9) becomes defective, a plurality of thin film transistors (11) are arranged. However, the display electrode (9) does not operate. The most defective process occurs during the manufacturing process. The gate electrode (2) and the auxiliary capacitance electrode (10) are formed immediately after the gate electrode (2) and the auxiliary capacitance electrode (10) are formed on the substrate (1). In some cases, dust or the like adheres to the surface of the display electrode, and after the insulating protective film is formed, the dust or the like is removed to form a pinhole, and the display electrode (9) and the auxiliary capacitance electrode (10) are short-circuited. When contact failure occurs between the semiconductor layer, the drain electrode (6) and the source electrode (7), each thin film transistor (1
1) may be defective at the same time. In this case, the pixel is completely defective and cannot be reproduced even if the present invention is used.

In the present invention, when the display electrode (9) and the auxiliary capacitance electrode (10) are short-circuited as described above,
It is to regenerate it so that it can be used again as a good product. By the way, as shown in FIG. 1, the auxiliary capacitance electrode (10) is overlapped with the display electrode (9) so as to form a ring around the display electrode (9) to form a capacitor having a desired capacitance. In this embodiment, the display electrode (9) is formed via the insulating layer (3) of the auxiliary capacitance electrode (10), but the electrodes (10) and (9) may be laminated in reverse.

The feature of the present invention resides in that a plurality of regions (at least two or more) are provided where the display electrode (9) and the auxiliary capacitance electrode (10) do not overlap each other.
That is, a notch (9A) is formed on each side of the display electrode (9) so that the display electrode (9) is recessed. As a result, a region where the display electrode (9) and the auxiliary capacitance electrode (10) do not overlap each other exists in the cutout portion (9A).
The cutout portion (9A) area is used during defective reproduction described later.

The substrate (1) on which the above-mentioned thin film transistor (11) is formed is integrated with a substrate (not shown) on which a light shielding film and a counter electrode are formed by a known method, and liquid crystal is injected into the space. Completed as a display panel for a projector. By the way, such a display panel is subjected to a predetermined inspection to check whether the plurality of thin film transistors (11) and the display electrodes (9) have malfunctions. For example, when various video signals are input to the thin film transistor (11) using a device such as a pattern generator, for example, when the thin film transistor (11) is normal and the display electrode (9) and the auxiliary capacitance electrode (10) are short-circuited ( The X portion shown in FIG. 1) and the display electrode (9) become white dots (or black dots) to notify the observer.

Therefore, according to the present invention, the auxiliary capacitance electrode (10) is broken in a region where the display electrode (9) and the auxiliary capacitance electrode (10) of the cutout portion (9A) do not overlap each other, resulting in a defect. The defective pixel is reproduced by electrically isolating the existing region. That is, when the display electrode (9) and the auxiliary capacitance electrode (10) are short-circuited in the X portion of FIG. 1, the cutout portion (9)
This is to disconnect the auxiliary capacitance electrode (10) in the AA and BB portions of (A) so that only the defective portion in the short-circuited portion becomes independent and the recess is reproduced as a good product.

The reproducing method will be briefly described. For example, polarizing plates are arranged above and below a display panel, and a black (or white) level signal is input to the panel from a pattern generator. Then, the display electrode (9) having a short-circuit defect displays a white (or black) dot. Next, as shown in FIG.
A display panel is placed on the stage of a microscope on which a laser or the like is set, and transmitted light is irradiated from the counter substrate (not shown) side so that a white (or black) point is placed within the field of view of the microscope. Furthermore, the short-circuited portion of the display electrode (9) and the auxiliary capacitance electrode (10) that cause the display electrode (9) to be white (or black) are electrically isolated. That is, laser light is applied to the area not overlapped by the cutout portion (9A) from the substrate (1) surface side for a predetermined time. Then, the auxiliary capacitance electrode (10) is melted and disconnected, and the short-circuited portion can be formed independently. At this time, the laser energy is stored in the auxiliary capacitance electrode (1
The thickness of the auxiliary capacitance electrode (10) is set to a necessary size so as to penetrate the thickness of (0) and the light shielding film or the counter electrode provided on the counter substrate (not shown) side is not substantially damaged and only the auxiliary capacitance electrode (10) is disconnected. For example, the thickness of the light shielding film of the counter substrate is 140
At 0 ~ 1500Å, the laser energy is about 20J
In that case, only the auxiliary capacitance electrode (10) can be disconnected.

In the present embodiment, after the display panel is completed, the chute portion is electrically independently reproduced by using the laser beam, but it can be similarly corrected even in the unfinished state. That is, by irradiating the laser beam from above the notch on the substrate (1) on which the thin film transistor is formed, it is possible to similarly break only the auxiliary capacitance electrode. But,
In the inspection process in this case, although it is possible to inspect the drain line and the gate line due to disconnection defects, it is difficult to determine whether each thin film transistor is good or defective, and in reality, it is performed for a completed product.

[0019]

As described in detail above, the liquid crystal display device according to the present invention includes a display electrode formed on an insulating substrate, a switching element connected to the display electrode, and a part of the display electrode. And a storage capacitor electrode formed via an insulating layer so as to overlap each other. The storage capacitor electrode is formed in a ring shape, and at least two or more portions of a region where the ring-shaped storage capacitor electrode and the display electrode overlap each other. The feature is that there is a region where they do not overlap.

The liquid crystal display device according to the present invention is
A display electrode provided with at least two cutouts on the periphery of the insulating substrate, a switching element connected to the display electrode, and a portion of the display electrode, which is overlapped with an insulating layer. It is characterized in that the auxiliary capacitance electrode is formed in a ring shape in the peripheral region of the display electrode, and the display electrode and the auxiliary capacitance electrode do not overlap with each other in the cutout portion.

Therefore, according to the present invention, by providing a region where the display electrode and the auxiliary capacitance electrode do not overlap with each other, even if these electrodes are short-circuited, the auxiliary capacitance electrode in the region where they do not overlap is disconnected. It is possible to reproduce by electrically separating the short section from other areas. Especially, the effect is great in the display panel for a projector used in the normally white mode.

[Brief description of drawings]

FIG. 1 is an enlarged plan view of an essential part showing a liquid crystal display device of the present invention.

FIG. 2 is a sectional view taken along line ZZ in FIG.

[Explanation of symbols]

(1) Insulating substrate (2) Gate electrode (3) Insulating protective film (4) Semiconductor layer (5) Passivation (6) Drain electrode (7) Source electrode (8) N ⁺ a-Si (9) Display electrode ( 10) Auxiliary capacitance electrode (9A) Notch

Claims (2)

[Claims] 1. A display electrode formed on an insulating substrate,
A switching element connected to the display electrode; and an auxiliary capacitance electrode that overlaps a portion of the display electrode and is formed via an insulating layer. The auxiliary capacitance electrode is formed in a ring shape, and the ring-shaped auxiliary capacitance is formed. A liquid crystal display device, characterized in that there is a region where they do not overlap in at least two portions of the region where the electrode and the display electrode overlap. 2. A display electrode formed on an insulating substrate, the display electrode being provided with at least two notches around the display electrode,
The display device includes a switching element connected to the display electrode, and an auxiliary capacitance electrode that overlaps a portion of the display electrode and is formed via an insulating layer, and the auxiliary capacitance electrode is formed in a ring shape in a peripheral region of the display electrode. The liquid crystal display device, wherein the display electrode and the auxiliary capacitance electrode do not overlap with each other in the cutout portion.