JPH0572559A - Liquid crystal display device - Google Patents

Abstract

PURPOSE:To lower the fraction defective of the liquid crystal display device and to prevent the temp. rise thereof by providing color filters on a 3rd insulating substrate and disposing this substrate on a 2nd insulating substrate which is the rear surface of the panel. CONSTITUTION:This display device has the transparent 1st insulating substrate 30 which has at least switching elements 31 and display electrodes 32, the transparent 2nd insulating substrate 40 which faces the 1st insulating substrate 30 and has at least a counter electrode 41, a liquid crystal crystal which is injected between the 1st and 2nd insulating substrates 30 and 40, and the transparent 3rd insulating substrate 50 which has the color filters 51. The panel is constituted in the state of excluding the color filters in such a manner and the 3rd insulating substrate 50 provided with the color filters 51 is separately provided, by which the color filters can be obtd. only in the non-defective panels. In addition, the heat generated by absorption of the light in the color filters is absorbed by the 3rd insulating substrate 50 having a high heat capacity, by which the temp. rise of the panel itself is prevented.

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,
In particular, it relates to a liquid crystal display device having improved characteristics including a color filter.

[0002]

2. Description of the Related Art At present, the LCD is the most advanced color display among various flat displays, and is attracting attention in the market. The reason is that the combination of the backlight and the color filter made it possible to realize colorization relatively easily. This structure is disclosed in, for example, Japanese Patent Laid-Open No. 3-137619, "Color Liquid Crystal Display" issued by Sangyo Tosho Co., Ltd., and the like.

FIG. 2 shows an example of the first insulating substrate (1) made of glass, which is hatched with diagonal lines on the lower side of the drawing. This substrate (1) has, for example, a TFT
(2) is formed, and the display electrode (3) is formed near the TFT (2). Further, an alignment film (5) is provided via the passivation layer (4). On the other hand, what is hatched on the upper side of the drawing is the second insulating substrate (6) made of glass. This board (6)
Is provided with a patterned color filter (7) indicated by X, and through the passivation layer (8),
A light-shielding film (9) is provided, and a counter electrode (10) and an alignment film (11) are sequentially laminated. Further, the first insulating substrate (1) and the second insulating substrate (6) are held at a constant interval by a spacer (12), and liquid crystal is injected between them, so that the substrates (1) and (6). On the back side of the
3) is stuck.

Light is incident from the direction of the light or the arrow to realize color display. As described above, the color filter is of the type provided between the substrates (1) and (6) and the type of attaching the color filter sheet to the back surface of the second insulating substrate (6) after making the liquid crystal panel. was there.

[0005]

In the former type in which a color filter is provided between the substrates (1) and (6), since the substrate (6) and the color filter (7) are bonded together, the defective rate is It is multiplied by the defect rate. The latter type, which is attached to the back surface of the substrate (6), is attached to a non-defective panel, so the defect rate is the defect rate of the color filter itself, but if it becomes defective, it is necessary to replace the color filter. Becomes

On the other hand, when these panels are applied to a projector, there is also a problem that the color filter absorbs light and tends to reach a high temperature.

[0007]

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and includes a transparent first insulating substrate (30) having at least a switching element (31) and a display electrode (32), Facing the first insulating substrate (30),
A transparent second insulating substrate (40) having at least a counter electrode (41), and liquid crystal injected between the first insulating substrate (30) and the second insulating substrate (40). ,
This is solved by having a transparent third insulating substrate (50) having a color filter (51).

[0008]

As described above, if the panel is constructed without the color filter and the third insulating substrate (50) provided with the color filter is separately provided, the color filter is provided only on the non-defective panel. Therefore, the yield is improved. Moreover, the heat generated by the absorption of light by the color filter is absorbed by the third insulating substrate (50) having a large heat capacity, so that the temperature of the panel itself can be prevented from rising. Further, the second insulating substrate (40) is replaced with the color filter (51).
If separated from the third insulative substrate (50) having the heat resistance, the thermal resistance becomes higher and the temperature rise can be prevented more efficiently.

[0009]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A schematic embodiment of the present invention will be described in detail below with reference to FIG. First there is a transparent first insulating substrate (30). The switching element (3
1) and a display electrode (32). The first insulating substrate (30) is made of, for example, glass, and two squares, large and small, are shown on the substrate (30). Small ones are switching elements such as TFTs and MIMs, and large ones. It is a display electrode. Further, an alignment film (34) is provided on the upper surface via a passivation layer (33). Naturally, these switching elements are arranged in a matrix, and a large number of lines are provided in the X and Y directions for selecting the switching elements, but they are omitted in the drawing.

Next is a transparent second insulating substrate (40). The substrate (40) is provided so as to face the first insulating substrate (30) and has at least a counter electrode (41) so that liquid crystal is injected therebetween. In FIG. 1, the light shielding film (42) is provided on the glass substrate (40). In this film (42), the display electrode (32) is
It is provided so as to be visible when light is transmitted, and is provided except for the surface of the second insulating substrate (40) corresponding to the display electrode. Furthermore, the passivation layer (4
The counter electrode (41) is provided via the electrode 3), and the alignment film (44) is provided thereon.

Further, there is a transparent third insulating substrate (50) having a color filter which is a feature of the present invention.
In FIG. 1, a color filter (51) is patterned and formed on a glass substrate (50). Although not shown in the figure, an overcoat layer made of transparent resin is formed. R. G. The pattern arrangement of B is a mosaic type,
There are a triangle type, a stripe type, a 4-pixel arrangement type, and the like, which are properly used depending on the purpose. Conventionally, the color filter is incorporated between the substrates (30) and (40), that is, in the liquid crystal cell. However, since the color filter (51) is formed on the substrate (50), the panel and the color filter are separated. It can be formed separately. Therefore, since the color filter can be attached to the non-defective panel, the yield can be improved more than ever before.

Furthermore, since the glass substrate (50) and the color filter (51) are separate from the panel, the heat generated by the light absorption of the color filter (51) does not directly raise the panel temperature. Moreover, since the glass itself has a heat capacity, the glass substrate (50) is first raised. The above is the case where the surface of the glass substrate (50) having the color filter (51) is provided in contact with the glass substrate (40). On the other hand, as in the case of a liquid crystal projector or the like, if the incident light is substantially parallel, the non-contact type may be used. That is, if the surface of the glass substrate (50) having the color filter (51) and the back surface of the glass substrate (40) are separated from each other, the heat generated between the glass substrate (50) having the color filter (51) and the glass substrate (40). The resistance increases and the temperature rise of the panel can be further prevented. Further, since the color filter is not incorporated in the liquid crystal cell, it is not subject to restrictions such as elution of ionic impurities and the like such as color change due to the alignment film, the light-shielding film and the sealing treatment.

Finally, polarizing plates (60) and (61) are provided. The polarizing plate (60) is provided on the back surface of the glass substrate (30), and the polarizing plate (61) is provided on the back surface of the glass substrate (50) or the glass substrate (40). In particular, when it is provided on the back surface of the glass substrate (50), the temperature rise due to the absorption of light by the polarizing plate (61) does not directly raise the panel temperature like the color filter described above.

Next, a concrete example using a TFT will be described with reference to FIG. First there is a first glass substrate (30). On this, TFT (31) and display electrode (32)
Is provided. TFT on the glass substrate (30)
Gate (70) of (31), gate line integrated with this gate, auxiliary capacitance electrode (71) and this electrode (71)
And an auxiliary capacitance line integrated therewith. The gate line and the auxiliary capacitance line are provided in parallel to prevent crossing.

Next, a single-layer or double-layer insulating layer (72) made of SiO ₂ and / or SiNx is deposited on the entire surface, and a non-doped non-single-crystal silicon film (73) is formed in the active region of the TFT (31). ), The N ⁺ -type non-single crystal silicon films (74) and (75) are formed in the source and drain regions in the upper layer. Here, the non-single-crystal silicon film is, for example, amorphous silicon or polycrystalline silicon. Further on the upper layer, there are a source electrode (76) and a drain electrode (77) made of Al, for example. The source electrode (76) is a display electrode (32) extending from the source (75) and overlapping with the auxiliary capacitance electrode (71).
Is electrically connected to. The drain electrode (77) is
It extends integrally from the drain (74) as a drain line. Further, an alignment film (34) is formed via a passivation layer (33) provided on the entire surface.

On the other hand, there is a second glass substrate (40),
A light-shielding film (42) is provided thereon, and a counter electrode (41) and an alignment film (44) are sequentially laminated on the entire surface with a passivation layer (43) interposed. Here, the passivation layer (43) may be omitted, or the counter electrode (4) may be omitted.
The stacking order of 1) and the light shielding film (42) may be reversed. Further, on the third glass substrate (50), the color filter (5
1) is formed, and an overcoat layer (7
8) is provided. Polarizing plates (60), (6) are formed on the back surfaces of the first glass substrate (30) and the third glass substrate (50).
1) is provided, and liquid crystal is injected between the first glass substrate (30) and the second glass substrate (40).

[0017]

As is apparent from the above description, since the color filter is combined with the non-defective panel, the overall yield can be improved. Further, since the third insulating substrate having the color filter is separate from the panel, it is possible to prevent the panel temperature from rising due to the absorption of light by the color filter. In particular, if the third insulating substrate having the color filter is provided apart from the back surface of the second insulating substrate, the effect is further enhanced. Further, since the heat capacity of the third insulating substrate and the polarizing plate is large, the speed of temperature rise can be suppressed, and the polarizing plate itself is not integrated with the panel, so that the temperature rise of the panel can be suppressed accordingly. Therefore, it is possible to prevent the deterioration of the elements and liquid crystal in the panel.

Furthermore, since the color filter is not provided in the panel, there is no restriction on the selection of materials such as elution of ionic impurities. Further, the color change of the filter itself does not occur due to the formation of the alignment film and the light-shielding film. As described above, high quality of the liquid crystal display device can be achieved by achieving the configuration of the present application.

[Brief description of drawings]

FIG. 1 is a schematic cross-sectional view of a liquid crystal display device showing an embodiment of the present invention.

FIG. 2 is a cross-sectional view of a conventional liquid crystal display device.

FIG. 3 is a cross-sectional view of a liquid crystal display device when a TFT is used in the present invention.

[Explanation of symbols]

 (30) First Insulating Substrate (31) Switching Element (32) Display Electrode (40) Second Insulating Substrate (41) Counter Electrode (50) Third Insulating Substrate (51) Color Filter

Claims (7)

[Claims] 1. A transparent first insulating substrate having at least a switching element and a display electrode; a transparent second insulating substrate facing the first insulating substrate and having at least a counter electrode; A liquid crystal display device comprising: a liquid crystal injected between the first insulating substrate and the second insulating substrate; and a transparent third insulating substrate having a color filter. 2. The surface of the third insulating substrate on which the color filter is formed is provided in contact with or away from the back surface of the second insulating substrate.
The described liquid crystal display device. 3. The liquid crystal display device according to claim 2, wherein a polarizing plate is formed on the back surface of the third insulating substrate. 4. The liquid crystal display device according to claim 1, wherein a polarizing plate is formed on the back surface of the second insulating substrate. 5. A transparent first insulating substrate, a gate line integrated with a gate, an auxiliary capacitance electrode formed so as not to intersect the gate line, and an auxiliary capacitance line integrated therewith, and substantially the entire surface. A non-doped non-single-crystal silicon film provided in the active region of the TFT having a gate as one structure, and a doped non-single-crystal silicon film formed in the source and drain regions of the TFT, The TF
A display electrode that is close to T and partially overlaps with the auxiliary capacitance electrode; a source electrode that electrically connects the source region and the display electrode; and a drain line that extends from the drain region. On the transparent second insulating substrate, which has at least an alignment film provided on the entire surface of the insulating substrate, a light-shielding film that substantially covers the display electrode region and a counter surface formed on the light-shielding film. At least an electrode and an alignment film formed on the counter electrode, at least a color filter on a transparent third insulating substrate, and the first insulating substrate and the second insulating substrate. A liquid crystal display device, in which liquid crystal is injected between the insulating substrates, and the surface of the third insulating substrate having the color filter is placed in contact with or separated from the second insulating substrate. 6. The liquid crystal display device according to claim 5, wherein polarizing plates are mounted on the back surface of the third insulating substrate and the back surface of the first insulating substrate. 7. A polarizing plate is placed on the back surface of the second insulating substrate and the back surface of the first insulating substrate, and the third polarizing plate is mounted on the back surface of the third insulating substrate.
6. The liquid crystal display device according to claim 5, wherein the surface of the insulating substrate having the color filter is placed in contact with or separated from the polarizing plate mounted on the second insulating substrate.