JPS63226626A - Color liquid crystal display element - Google Patents

Abstract

PURPOSE:To increase the display contrast of the titled element by providing an insulat ing black mask by intersecting orthogonally with a conductive black mask, in a gap between each sections of a color filter layer, and conducting a lower transparent electrode with an upper transparent electrode through the conductive black mask. CONSTITUTION:The plural stripe like picture element electrode 12 are formed on the inner side of a display substrate plate 11, and an orientation film 13 is formed on the inner surface of the electrode. In the another side, the plural stripe like lower transparent electrode 20 is formed on the inner surface of a counter substrate plate 14 by intersecting orthogonally with the electrode 12. The plural conductive black masks 21 are formed on the electrode 20, by intersecting orthogonally with the elec trode 20, and the color filter layer 16 is formed by segmenting it at every color. The plural insulating black masks 22 are formed in the gap of the another direction be tween sections at every color of the filter layer 16, by intersecting orthogonally with the mask 21. Next, the plural upper transparent electrodes 23 are formed on the filter 16, and the electrodes 23 and 20 are conducted through the mask 21. And, the substrates 11 and 14 are countered after forming the orientation film 18 on the substrate, and the liquid crystal 19 is injected between the substrates to complete the cell. Thus, the display contrast of the titled element can be improved.

Description

DETAILED DESCRIPTION OF THE INVENTION TECHNICAL FIELD The present invention relates to an improvement in a color liquid crystal display device for quizzes, which has color filters of three primary colors divided by color and a black mask that blocks light from each other.

"Prior Art and its Problems" A color liquid crystal display element employed in a liquid crystal color television or the like has a large number of pixel electrodes, and color filters of three primary colors are provided corresponding to each pixel electrode. Then, by applying a selection voltage to an arbitrary pixel electrode, a color corresponding to that pixel electrode f is displayed, thereby making it possible to display a free pattern of color by combining dots of the three primary colors.

Among such color liquid crystal display devices, a quiz device has been proposed in which the three primary colors of a color filter are divided by color using a black mask to block light from each other. This color liquid crystal display element will be explained according to FIG. 4. On the inner surface of the display substrate 11, there are a plurality of pixel electrodes 12 (single in the figure due to the relationship with the cross-sectional display area) and an alignment film 13.
are formed in layers. On the other hand, on the inner surface of the counter substrate 14, a plurality of transparent electrodes 15 are formed in a stripe shape orthogonal to the running direction of the pixel electrodes 12. On the transparent electrode 15, three primary colors, namely edge 16G, blue 16B and red 16
A color filter N16 consisting of 8 color filters is formed with a gap between each color, and the gap and each transparent electrode 15
A black mask 17 that is orthogonal to each other in a grid pattern is formed in the gaps. This black mask 17 divides each color of the color filter layer 16 and blocks light at each boundary, and is made of an insulating resin material. Roughly speaking, an orientation 1118 is formed on the color filter layer 16 and the black mask 17. The display substrate 11 and the counter substrate 14 are arranged to face each other with their respective electrode forming surfaces inside, and the circumference I11 is sealed with a predetermined cell gap, and a liquid crystal 19 is sealed inside.

In such a color liquid crystal display element, when a voltage is applied to the pixel electrode 12 and the transparent electrode 15 in the dark, the optical rotation power of the liquid crystal 19 in the part corresponding to the electrode to which the voltage is applied disappears. Lower polarizing plate (not shown), counter substrate 1
4. Each color of the color filter layer 16, green 16G, blue 1
The backlight light that has passed through the 6B and red 16H films is transmitted through the display substrate 11 and the upper polarizing plate (not shown) only in the above portions. Therefore, by the color filter layer 16 corresponding to the voltage application portion, the green 1
It can be visually recognized from the display screen as light colored by 6G, blue 16B, and red 16B. By selecting the pixel electrode 12 and the transparent electrode 15 to which a voltage is applied, color display in a free pattern consisting of the three primary colors becomes possible.

However, in the conventional color liquid crystal display element described above, a color filter layer 16 is formed on the transparent electrode 15, and this color filter layer 16 is connected to the pixel electrode 12 and the transparent electrode 15.
Therefore, even if a predetermined voltage is applied between the pixel electrode 12 and the transparent electrode 15, the color filter layer 16 may cause the voltage to drop below the predetermined value. It may become impossible to obtain the necessary threshold voltage for the liquid crystal 19, causing variations in the rise of the liquid crystal 19 and reducing display contrast.Also, if a partial disconnection occurs in the transparent conductor 8i15, the In this case, the display will be missing, resulting in a fatal line defect.

OBJECTS OF THE INVENTION The present invention solves the above-mentioned problems, and aims to prevent the voltage applied between the electrodes from dropping, maintain the liquid crystal threshold 1ilFr at a predetermined value, and improve display contrast. Another object of the present invention is to provide a color liquid crystal display element that does not cause a fatal line defect even if a portion of the transparent electrode is disconnected.

"Structure of the Invention" The present invention provides a plurality of lower transparent electrodes on the inner surface of at least one substrate, a plurality of conductive black masks formed on the lower transparent electrodes perpendicularly to the electrodes, and a plurality of conductive black masks formed on the lower electrodes. A color filter layer of three primary colors formed into sections for each color with a conductive black mask in between, and a plurality of insulating black masks formed perpendicularly to the conductive black mask in the gaps between each section of this color filter layer. and an upper transparent electrode formed on the color filter layer and the conductive black mask and facing the lower transparent electrode, the lower transparent electrode and the upper transparent electrode being electrically connected through the conductive black mask. It is characterized by

In this way, in the present invention, the black mask that partitions each color of the color filter layer consisting of the three primary colors and blocks light is composed of a conductive mask and an insulating mask, and a voltage is applied between the pixel electrode and the black mask. The transparent electrode for applying the voltage is composed of a lower transparent electrode formed under the color filter layer and an upper electrode formed above the color filter layer, and these two electrodes are electrically connected through a conductive black mask. Therefore, when a predetermined voltage is applied between the pixel electrode and the above two types of electrodes, the applied voltage between the lower transparent electrode and the pixel electrode, which drops due to the black mask, is reduced between the upper transparent electrode and the pixel electrode. Since the applied voltage is compensated for by the applied voltage, it is possible to prevent the applied voltage from falling below a predetermined value. If the applied voltage is maintained at a predetermined value in this way, the threshold value of the liquid crystal will not fluctuate, the liquid crystal will rise well, and the display contrast can be improved. In addition, even if the upper transparent electrode or the color filter layer breaks due to expansion and contraction, the voltage can be applied to the pixel electrode at the lower transparent electrode, so even if the applied voltage may drop, there is no fatal line. Since it does not become a defect, the yield of the product improves.

"Embodiment of the Invention" An embodiment of the color liquid crystal display element according to the present invention will be explained below with reference to the drawings. Incidentally, members common to those in FIG. 4 are given the same reference numerals.

FIGS. 1 and 2 show cross sections of the color liquid crystal display element of the present invention from different directions, respectively. To explain this according to the manufacturing process, first, a plurality of pixel electrodes 12 made of ITOII or the like are formed in stripes on the inner surface of a display substrate 11 made of a glass plate, and an alignment film 13 is formed on the rough inner surface. This alignment film 13 is formed by, for example, printing and coating a polyimide resin or the like, and heating and drying it for a predetermined period of time. On the other hand, on the inner surface of the counter substrate 14, which is also made of a glass plate, a plurality of striped patterns are formed such that lower transparent electrodes 201fr made of an ITO film or the like are perpendicular to the pixel electrodes 12.

Next, this lower transparent electrode 20 is placed on top of the lower transparent electrode 20.
A plurality of conductive black masks 21 are patterned into thin stripes so as to be orthogonal to each other. This conductive black mask 21 is made of, for example, chromium, nickel, etc.
! A conductive gold gIA having the following properties is formed by a spackling method or a vapor deposition method.

Note that it is preferable that the conductive black mask 21 has the same thickness as the color filter layer 16 formed in the next step.

Roughly on the lower transparent electrode 20, next, a color filter layer 16 consisting of three primary colors is formed in sections for each color.

At this time, the conductive black mask 21 is sandwiched between the unidirectional gaps between the divided colors, and plays the role of transmitting light between each color, i.e., green 16G.
, Blue 16B, and Red +68 are produced by, for example, printing a photosensitive gelatin-based resin, patterning and dyeing by photolithography, or offset printing with a resin ink containing pigment or dye.
They are formed sequentially for each color.

Next, a plurality of insulating black masks 22 are placed in the gaps in the other direction between the colors of the color filter layer 16 formed in this way, in order to achieve continuous light of each color. Form a pattern into thin stripes. This insulating black mask 22 is formed perpendicularly to the conductive black mask 21. The insulating black mask 22 is formed, for example, by applying a photosensitive resin such as black gelatin and patterning it by photolithography, or by offset printing a black resin ink.

Next, a plurality of upper transparent electrodes 23 made of an ITO film or the like are patterned on the color filter layer 16 and the conductive black mask 21 so as to face the lower transparent electrodes 20 . This upper transparent electrode 23 is preferably formed by a mask sputtering method or a mask evaporation method, so that the upper transparent electrode 23 and the lower transparent electrode 20 are electrically connected through the conductive black mask 21. Further, on this upper transparent electrode 23, an alignment film 18 made of polyimide resin or the like is formed.

Then, the display substrate 11 and the counter substrate 14 are made to face each other with their electrode forming surfaces inside, and a gap material (not shown) is formed.
After intervening, the peripheral portion is sealed to form a liquid crystal cell. At the very least, this cell has a 19v liquid crystal! A color liquid crystal display element is obtained.

In the color liquid crystal display element manufactured by the above process, when a voltage is applied between the pixel electrode 12 and the lower transparent electrode 20 and upper transparent electrode 23 that are mutually conductive, the electrodes in the part where the voltage is applied are The optical rotation power of the liquid crystal 19 in the corresponding portion disappears. Therefore, the lower polarizing plate (not shown)
, the counter substrate 14, and the color filter layer 16, which are the edges 16G, blue 168, and red 16B, transmit the backlight light that passes through the display substrate 11 only in the above portions.
and an upper polarizing plate (not shown). As a result, from the display surface, light colored with green 16G, blue 168, and red +6R of the color filter layer 16 corresponding to the voltage application portion is visible.

In this state, if a voltage of a predetermined value is applied between the pixel electrode 12, the lower transparent electrode 20, and the upper transparent electrode 23, the voltage that should be lowered to a predetermined value or less by the color filter layer 16 will be applied to the pixel electrode. 12 and the upper transparent electrode 23 are supplemented by voltages in the dark. Therefore, the applied voltage is maintained at a predetermined value. If the applied voltage is maintained at a predetermined value in this manner, the threshold value of the liquid crystal does not decrease, so that the liquid crystal rises well and the display contrast improves. Furthermore, in the present invention, since voltage is applied to the pixel electrode 12 using two types of mutually conductive electrodes, the lower transparent electrode 2G and the upper transparent electrode 23, the color filter layer 16 is applied to the upper transparent electrode 23. Even if a disconnection occurs due to expansion or contraction of the pixel electrode 12, voltage can be applied to any of the pixel electrodes 12 using the lower transparent electrode 20.

It should be noted that, although the above embodiments are explained using a simple matrix squib, the present invention can also be applied to a color liquid crystal display element using an active matrix.

"Effects of the Invention" As explained above, the present invention comprises a black mask formed at the boundary of each color of a color filter layer consisting of three primary colors, which is made of a conductive material and an insulating material. , the transparent electrode is composed of a lower transparent electrode formed under the color filter layer and an upper electrode formed above the color filter layer, and these electrodes are electrically connected through a conductive black mask. Therefore, the voltage applied between the pixel electrode and the two electrodes can be maintained at a predetermined value at the time of application without being lowered by the color filter layer. If the applied voltage is maintained at a predetermined value, the threshold value of the liquid crystal does not decrease and fluctuations occur, so that the liquid crystal rises well and the display contrast improves. Also, the voltage is
Since the voltage is applied between the pixel electrode and the above two types of mutually conductive electrodes, even if the upper transparent electrode is disconnected due to expansion and contraction of the color filter layer, the lower electrode and the pixel electrode will still be electrically conductive. Therefore, although a decrease in display contrast may occur due to voltage drop, fatal line defects can be prevented and product yield can be improved.

[Brief explanation of drawings]

1 is a sectional view taken along the line II in FIG. 3, showing an embodiment of a color liquid crystal display element according to the present invention; FIG. 2 is a sectional view taken along the line ■-■ in FIG. 1; This figure is a plan view of the counter substrate side showing the state before formation of the upper transparent electrode in FIGS. 1 and 2, and FIG. 4 is a sectional view of a conventional liquid crystal display element. In the figure, 11 is a display substrate, 12 is a pixel electrode, 14 is a counter substrate, 16 is a color filter layer, 20 is a lower transparent electrode, 2
1 is a conductive black mask, 22 is an insulating black mask, and 23 is an upper transparent electrode. Patent applicant Alps Electric Co., Ltd. Agent
Kunio Miura and Shigeru Matsui" Figure 1 Figure 2

Claims (1)

[Claims] (1) A plurality of lower transparent electrodes on the inner surface of at least one substrate, a plurality of conductive black masks formed on the lower transparent electrodes perpendicular to the electrodes, and a conductive black mask on the lower electrodes. A color filter layer of three primary colors that is sandwiched and formed into sections for each color, a plurality of insulating black masks formed perpendicularly to the conductive black mask in the gaps between each section of this color filter layer, and the color filter layer. A color liquid crystal comprising an upper transparent electrode formed on a conductive black mask and facing the lower transparent electrode, the lower transparent electrode and the upper transparent electrode being electrically connected through the conductive black mask. display element.