JPH0291618A - Display panel - Google Patents

Abstract

PURPOSE:To obtain a large-screen liquid crystal display panel free from degradation in picture quality by leading out leader lines of one transparent electrodes out of X and Y transparent electrodes orthogonal to each other from parts other than display picture elements in parallel with the other transparent electrodes. CONSTITUTION:Y transparent electrodes 66 are led out as leader lines 3 of Y transparent electrodes from intersection parts e1 to e6 of Y transparent electrode leader lines in parallel with X transparent electrodes 65. Leader lines 3 of Y transparent electrodes pass between display picture elements on X transparent electrodes 65 and are led out to terminal taking-out ports d1 to d6 of Y transparent electrodes. Consequently, transparent insulating materials 1 are arranged in all parts intersecting Y transparent electrodes 66. An insulating material of high transmittance like an SiO or an SiO2 is used as the transparent insulating material 1, and a conductive material of high transmittance is used as the material of Y transparent electrode leader lines 3. Thus, the display picture quality is not degraded though transparent insulating material 1 and Y transparent electrode leader lines 3 are arranged.

Description

[Detailed Description of the Invention] [Industrial Application Field] This invention relates to a display panel and (
This relates to a display panel in which the X and Y transparent electrode extraction terminals of a display panel having Y transparent electrodes are on the same side.

FIG. FIG. 7 is a sectional view taken along line 8-A in FIG. 6. In Figures 6 and 7, (6
0) is a liquid crystal display i (panel), (61) is a top glass substrate,
(62) is the lower glass substrate, (63) and (64) are the polarizing films, (65) (!X transparent electrode, (6B>(iY transparent electrode,
(67) is a sealant, (68) is a liquid crystal, (69) is a display pixel, (70) is a terminal extraction part of the X transparent electrode, (71)
> is the terminal extraction part of the Y transparent electrode.

Next, the operation of the liquid crystal display panel (60>) will be explained.

In side-lit twisted nematic type liquid crystal display elements, the long axis direction of the liquid crystal (68) molecules is usually (X transparent electrode (65)
), when no voltage is applied to the Y transparent electrode (66)) The wall surface in contact with the liquid crystal (68) is subjected to a rubbing process or an oblique vapor deposition process, so that the upper and lower glasses are oriented at right angles to each other. This twisted the liquid crystal molecules continuously so that they formed a right angle between the upper and lower glass substrates. This is a so-called twisted nematic state. At this time, the light irradiated from the lower glass substrate (62) side is linearly polarized by the polarizing film (64), rotated 90 degrees by the liquid crystal (68), and then passes through the upper glass substrate (61) and becomes polarized. The light passes through a polarized light till (63) arranged to match the direction.

As a result, when looking at the liquid crystal display panel (60) from the top glass substrate <61> side, the entire liquid crystal display panel (60> becomes a --like bright screen due to the light emitted from the bottom glass substrate (62). Look and see.

Next, pass the terminal take-out part (7o) of the X transparent electrode and the terminal take-out part <71 of the Y transparent electrode, and then
5) and the Y transparent electrode (66), the liquid crystal (68) in the area sandwiched between the electrodes (display pixel (69)) is oriented perpendicularly to the glass substrate. Eliminate light distortion. In other words, the light irradiated from the lower glass substrate (62) side becomes linearly polarized light after passing through the polarizing film (64), and the light travels straight without being polarized by the liquid crystal (68). 64) and polarizing film (63)
If the polarization angles of the liquid crystals (68) and (63) are different from each other by 90 degrees, the light passing through the liquid crystal (68) will be blocked by the polarizing film (63).At this time, the upper glass substrate (
If you look at the liquid crystal display panel (6o) from the 61> side, you will see the part where voltage is applied between the
)) only becomes dark. This darkened area is displayed as a display image. In other words, a so-called positive type display is created in which dark areas correspond to text/graphic images and video areas, and bright areas correspond to background images. If the angle of the polarizing film <63) is shifted by 90 degrees, the above relationship between bright and dark areas is reversed, resulting in a so-called negative type display.

[Problems to be Solved by the Invention] Conventional display panels are constructed as described above, and when a large screen liquid crystal display panel is constructed by arranging a large number of such liquid crystal display panels (60) vertically and horizontally. Let's think about it.

FIG. 8 is an example of this. In this example, a set of four liquid crystal display panels (60) is used. With this arrangement, the sealant (67) of the liquid crystal display panel (60>) is in contact with each other, so there is less deterioration in image quality due to the arrangement.
The size of the contacting portion of the upper and lower glass (61) (62) of 67) is such that the display pixel of the liquid crystal display panel (60) is less than 69.
), so even if these parts are brought into contact to create a larger screen, the seams are difficult to see (and there is no major deterioration in image quality.However, with this arrangement method, the size of the LCD panel ( 60).For this reason, if you want to realize an even larger liquid crystal display panel, you can use a liquid crystal display panel (60) as shown in Figure 9.
A conceivable arrangement method is to bring the sealant (67) part of the Y transparent electrode into contact with the terminal takeout part (71>) of the Y transparent electrode. Since the width in the take-out direction of 〉 is extremely large compared to the size between the display pixels (69) of the liquid crystal display panel (60〉), the seams caused by the arrangement are noticeable.This causes extremely large deterioration in image quality. become.

(For example, the magazine r National Te-chn
ical Report Vol. 33 No. I
Feb. 1987 J.P., 27) In this way, when attempting to realize a large-screen liquid crystal display panel using the conventional liquid crystal display panel (60), an arrangement method with less deterioration in image quality as shown in FIG. Arrangement methods that attempt to realize a larger screen, such as those shown in FIG. 9, have the disadvantage of resulting in a liquid crystal display panel with significant image quality deterioration.

The second invention was made in order to solve the above-mentioned drawbacks, and provides a large-screen display panel that can increase the size of the liquid crystal display panel and does not cause deterioration in image quality.

[Means for Solving the Problems] The display panel according to the present invention is characterized in that the lead line of one of the Y transparent electrodes is provided in a direction parallel to the other transparent electrode from a portion that is not a display pixel. At the same time, an insulator is provided at a portion where the extending line of the transparent electrode intersects with the transparent electrode on the same substrate so that the extending line of the transparent electrode and the transparent electrode do not come into electrical contact with each other. The lead terminals of the transparent electrodes are located on the same side.

[Function] Even if the display panel of the present invention is arranged vertically or horizontally to form a large screen display panel, the seams caused by the arrangement are not noticeable, and a large screen display panel without image quality deterioration can be realized. .

[Embodiment] FIG. 1 is a plan configuration diagram of a liquid crystal display panel according to an embodiment of the present invention, viewed from above. Figure 2 shows B- in Figure 1.
It is a sectional view along the B line. In Figures 1 and 2,
(1) is a transparent insulator, (2> is a lead line from the X transparent electrode (65), (3) is a lead line from the Y transparent electrode (66>),
m + I Nm + 6 is the Y transparent electrode number of the Y transparent electrode (66), n+INn+6 is the X of the X transparent electrode <65>
Transparent electrode number, b+l Nb+5 is the number between X transparent electrodes, (cl> to (c6) are the terminal openings for taking out the X transparent electrode, (dl) to (d6> are the terminal openings for taking out the Y transparent electrode,
(el) to <e6) are the intersections of the Y transparent electrode (66) and the Y transparent electrode lead line (3>).

The operation of the liquid crystal display panel (60) is similar to the conventional one. In other words, in the side-lit twisted nematic type liquid crystal display element, the long axis direction of the molecules of the liquid crystal (68) is
Normally (when no voltage is applied to the X transparent electrode (65) and the Y transparent electrode (66)), the wall surface in contact with the liquid crystal (68) is subjected to rubbing treatment or diagonal vapor deposition treatment, so that the upper and lower glasses are mutually connected to each other. Oriented at right angles. This is a so-called twisted nematic state in which the liquid crystal molecules are continuously twisted at right angles between the upper and lower glass substrates.

At this time, the light irradiated from the lower glass substrate (62) side is linearly polarized by the polarizing film (64), rotated by 90 degrees by the liquid crystal (68), and then passes through the upper glass substrate 61). Polarizing film (63) provided to match the polarization direction
Go through. As a result, when looking at the liquid crystal display panel (60) from the upper glass substrate (61) side, the lower glass substrate (62
), the entire liquid crystal display panel (60) appears as a --like bright screen.

Next, the terminal opening of the X transparent electrode (cl) to (c
6) and the terminal outlet of the Y transparent electrode (dl) ~ (
d2) Through the X transparent electrode (65),! : When a predetermined voltage is applied between the Y transparent electrodes (66), the liquid crystal (68) in the portion sandwiched between the electrodes (display pixels (69)) changes direction perpendicular to the glass substrate and twists. Eliminate.

In other words, the light irradiated from the lower glass substrate (62) side becomes linearly polarized light after passing through the polarizing film (64), and the light travels straight without being polarized by the liquid crystal (68). If the polarization angles of the liquid crystal (68) and the polarization film (63) are set to be 90 degrees different from each other, the light passing through the liquid crystal (68) will be blocked by the polarization film (63). At this time, when looking at the liquid crystal display panel (60) from the top glass substrate (61) side, only the part (display pixel (69)) where voltage is applied between the X and Y transparent electrodes becomes dark. The portion is displayed as a display image. In other words, the dark portion corresponds to the character/graphic image and the video portion, and the bright portion corresponds to the background image, resulting in a so-called positive display.

If the angle of the polarizing film (63) is shifted by 90 degrees, the above relationship between bright and dark areas is reversed, resulting in a so-called negative type display.

Here, a feature of the present invention is that even if liquid crystal display panels are arranged vertically and horizontally to form a large-screen liquid crystal display panel, in order to create a structure in which the seams caused by the arrangement are not noticeable, the removal of the transparent electrodes is not required. The transparent insulator (1) is structured so that the sealant is concentrated on the same side, and the sealant is on the outer wall of the remaining three sides. , the part where the lead line (3) from the Y transparent electrode (66) intersects with the Y transparent electrode (66) between display pixels (69) (for example, the part where the X transparent electrode number b+2 and the Y transparent electrode number m+1 intersect) ), the lead wire (3) from the Y transparent electrode (66>) and the Y transparent electrode (66) are attached to prevent electrical contact.In other words, the transparent insulator (1 ) is arranged at the intermediate layer position between the Y transparent electrode (66>) and the Y transparent electrode lead line (3), as shown in FIG.

In this way, the Y transparent electrode (66) is moved in the direction parallel to the X transparent electrode (65) as the Y transparent electrode lead line (3) from the intersection points (el) to (e6) of the Y transparent electrode lead lines. drawn out. The lead line (3) of the Y transparent electrode passes between the display pixels (69) on the X transparent electrode (65) and is led out to the terminal outlet (di) to <d6) of the Y transparent electrode. Therefore, the transparent insulator (1) is provided in all the parts intersecting with the Y transparent electrode (66). The lead line (2) of the X transparent electrode is led out to the terminal outlet (C1) to <C6) of the X transparent electrode. Y at the end
For the Y transparent electrode lead line (3) from the intersection point (C6) of the transparent electrode lead lines, the X transparent electrode distance number b+s
It is taken out to the outside from the intersection of the Y transparent electrode number m+6 and the Y transparent electrode number m+6.

By adopting such an electrode structure, a sealant (67) for sealing the liquid crystal is placed on the outer walls of three sides of the rectangular liquid crystal display panel (67). The width is a small value ranging from several hundred microns to around lrnm at most.

Here, the transparent insulator (1) includes an insulating material with high transmittance,
For example, the lead line of Y transparent electrode (SiO, 5iOz, etc.
For 3), a conductive material with high transmittance is used.

Thereby, even if the transparent electrode (1) and the lead line 3) of the Y transparent electrode are provided, the display image quality will not deteriorate.

The lead lines (3) of the Y transparent electrode are led out to the terminal extraction terminal openings (dl) to (d6) of the Y transparent electrode without crossing each other. Similarly, the lead lines (2) of the X transparent electrodes are led out to the terminal ports (cl) to (C6) without intersecting each other. The lead line (2) of the X transparent electrode deposited on (61) and the bottom glass substrate (62)
), there is a gap of several microns to more than ten microns between the lead wires (3) of the Y transparent electrodes deposited on the transparent electrodes (2) and (3).
Coat a thin layer of insulating material on the transparent electrode lead wires (2) and (3) to prevent electrical contact (
.

The top and bottom glasses (61 bars 62) are designed so that the extraction terminal openings of each transparent electrode can be easily connected to external connectors.
For example, as shown in FIG. 3, they are shaped with cuts so that they do not overlap each other.

Now, an embodiment of a large screen liquid crystal display panel using a liquid crystal display panel according to an embodiment of the present invention will be described.

FIG. 4 shows an example of a liquid crystal display panel according to the present invention constructed of four horizontally and two vertically. FIG. 5 is an enlarged drawing of the part surrounded by circle a in FIG. 4. In the liquid crystal display panel according to an embodiment of the second aspect of the invention, even if the panels are arranged as shown in the figure, the parts that come in contact with each other become parts of the sealant (67), so the size of the seam caused by the arrangement is small.

Furthermore, to be more precise, if the width of the sealant is f as shown in FIG. By setting this value and arranging the liquid crystal display panels horizontally and vertically, a large-screen liquid crystal display panel with no deterioration in image quality can be realized.

Furthermore, by coating the display pixels (69) with R (red), G (green), and B (blue) color filters, a liquid crystal display panel that can easily display colors can be provided. ) Moreover, this invention is not limited to liquid crystal display panels, but also applies to X,
This invention can be applied to display panels having a Y transparent electrode structure.

[Effects of the Invention] As described above, according to the present invention, the lead line of one of the X and Y transparent electrodes is provided in a direction parallel to the other transparent electrode from a portion that is not a display pixel. At the same time, an insulator is provided at a portion where the lead line of the transparent electrode intersects with the transparent electrode on the same substrate so that the lead line of the transparent electrode and the transparent electrode do not come into electrical contact, and both transparent Since the electrode extraction terminals are arranged on the same side, the large-screen liquid crystal display panel has the effect of not deteriorating the image quality even if the display panel is arranged horizontally or vertically.

[Brief explanation of drawings]

FIG. 1 is a plan configuration diagram of a liquid crystal display panel according to an embodiment of the present invention viewed from above, FIG. 2 is a sectional view taken along line B-B in FIG. 1, and FIG. FIG. 4 is a plan configuration diagram showing the shape of the upper and lower glass substrates of a liquid crystal display panel according to an embodiment of the present invention, which shows a large screen constructed by arranging four liquid crystal display panels horizontally and two vertically. FIG. 5 is an enlarged plan configuration diagram of FIG. 4; FIG. 6 is a plan configuration diagram showing a conventional liquid crystal display panel;
FIG. 7 is a sectional view taken along line A-A in FIG. 6, and FIGS. 8 and 9 are plan configuration diagrams showing a large screen display panel constructed by combining conventional liquid crystal display panels. be. In the figure, (l) is an insulator, (2)<3) is a leader line, (60) is a display panel, (61) and (62) are glass substrates, (65) is an X transparent electrode, and (66) is a Y Transparent electrode, (
69) are display pixels, (cl) to (c6), (di> to
(d6) is an output terminal opening. In addition, the same symbols in the figures indicate the same or equivalent parts.

Claims (1)

[Claims] In a display panel consisting of two glass substrates having X and Y transparent electrodes that are perpendicular to each other, a lead line of one of the X and Y transparent electrodes is drawn parallel to the other transparent electrode from a part that is not a display pixel. At the same time, an insulator is provided at the portion where the lead line of the transparent electrode intersects with the transparent electrode on the same substrate so that the lead line of the transparent electrode and the transparent electrode do not come into electrical contact. A display panel in which the output terminals of both transparent electrodes are located on the same side.