JPS62153823A - Liquid crystal shutter - Google Patents

Abstract

PURPOSE:To obtain images having a high contrast by forming color filters as light shielding members on a pair of substrates and forming shutter windows with these color filters. CONSTITUTION:A voltage is applied between segment electrodes 11..., 11... and common electrodes 7 and 7 in individual shutter parts in accordance with the signal from a shutter driving circuit to operate a liquid crystal LC, and each shutter part is opened or closed selectively. In the shutter part in the open state, the light from a light source is made incident on the liquid crystal LC through the common electrode 7 and a shutter window 9 of a common substrate 1. In this case, the light is absorbed and intercepted by a color filter 8 and is not transmitted in the part other than the shutter window 9, and a part spread in accordance with scattering of the light is cut by a color filter 15 covering the part other than a shutter window 16 when it passes the shutter window 16, thus preventing the leak of light.

Description

[Detailed description of the invention] [Technical field of invention] The present invention relates to a donation shutter.

[Technical overview of the invention and its problems]

Recently, in image display on television receivers and optical writing in optical writing printers used in office equipment, many minute shutter parts are arranged with close gaps to control the transmission of light. A liquid crystal shutter is used.

This liquid crystal shutter has a pair of substrates made of transparent glass plates facing each other with a liquid crystal in between, and a large number of segment electrodes made of transparent electrodes are arranged and formed on the inner surface of one substrate, and the segment electrodes made of transparent electrodes are formed on the inner surface of the other substrate. A common electrode made of a transparent electrode is formed opposite to the segment electrode array, and a metal film is further formed on the other surface of the common electrode so as to form shutter windows facing each of the segment electrodes individually. A large number of shutter parts are arranged and formed by segment electrodes and a common substrate exposed through a shutter window facing the segment electrodes.

Then, by applying an electric field between the segment electrode and the common electrode from the drive circuit to control the behavior of the liquid crystal between the substrates, each shutter section is opened or closed. The transmission of light can be controlled by By controlling the transmission of light, an image consisting of a large number of dots arranged corresponding to each shutter portion is formed.

In such a conventional liquid crystal shutter, when the shutter section is "open", light from the light source passes through the shutter window of the common substrate, the liquid crystal, and the segment electrode of the segment substrate in this order. However, in this case, when light enters the liquid crystal from the shutter window of the common substrate, the light passes through the liquid crystal with a spread that is treated as scattered light. For this reason, the light that passes through the segment electrodes from the liquid crystal spreads to other areas on the outer periphery of the shutter section, that is, it leaks, and the dot images formed at the shutter section have blurred outlines. Become. Therefore, there is a problem in that the contrast of the image of the dot array formed by the entire liquid crystal shutter is reduced, making it impossible to obtain a clear image.

For this reason, a light shielding member is provided on both the segment board and the common board, respectively, and the inner light member allows the segment [pole and common 1! , a shutter window is formed on each of the lumberjacks, and the combination of both shutters B defines the light transmission area at the shutter part, eliminating the influence of scattered light on the shutter part and obtaining a high-contrast image. It is being considered to do so.

However, in this type of liquid crystal shutter, light shielding members are formed on both the segment board and the common board, so
There is a need for a light shielding member that can be easily formed and has improved productivity.

[Purpose of the invention]

The present invention was made based on the above-mentioned circumstances, and an object of the present invention is to provide a liquid crystal shutter that allows easy formation of a light shielding member and has good manufacturability.

[Summary of the invention]

The liquid crystal shutter of the present invention has a segment electrode and a common electrode formed on the inner surfaces of a pair of substrates facing each other with a liquid crystal sandwiched therebetween to form a shutter section for controlling light transmission. A colored filter is formed to define a light transmission area in each of the segment electrodes and the common electrode to prevent light leakage due to light scattering in the liquid crystal, and a colored filter that can be easily formed as a light shielding member is provided. This results in improved manufacturability.

[Embodiments of the invention]

Embodiments of the present invention will be described below with reference to drawings.

As an example, a liquid crystal shutter used for optical writing of an optical writing type blink will be explained. The optical writing system controls the transmission of light from a light source using a liquid crystal shutter in the optical recording frame, forms an electrostatic image consisting of a row of dots on the surface of the photosensitive drum, and transfers this i# electrostatic image toner. It is something that is transferred to paper after being developed.

The liquid crystal shutter used for optical writing in an optical writing printer is a horizontally elongated shutter installed parallel to the axial direction of the photosensitive drum, and has a large number of shutter parts arranged in a longitudinal direction.

1 to 5 show a liquid crystal shutter made of the GH effect used in an optical writing printer as an embodiment of the present invention.

In the figure, reference numerals 1 and 2 denote a common substrate and a segment substrate made of transparent glass plates, and the common substrate 1 and segment substrate 2 are arranged vertically facing each other as shown in FIG. 2181 and FIG. They are in contact with each other with inner sealing materials 4, 4 interposed therebetween. The outer sealing material 3 has a horizontally elongated frame shape, and the inner sealing materials 4, 4 are formed parallel to each other and housed inside both sides of the outer sealing material 3 in the longitudinal direction of the substrate. Both ends of the inner sealing materials 4, 4 are connected to both sides of the outer sealing material 3, respectively, and are surrounded by both sides of the outer sealing material 3 between the substrates 1, 20 and the inner sealing materials 4, 4. The portions are spaces 5, 5 filled with air.

Both ends of the narrow portion formed between the inner sealing materials 4, 4 are communicated with wide width portions at both ends of the outer sealing material 3,
A narrow portion and a wide portion between the substrates 1 and 2 are filled with a GH effect type liquid crystal LC. Note that 6 in the figure is a liquid crystal injection hole formed in the outer sealing material 3, which is sealed after the liquid crystal LC is injected.

On the inner surface of the common substrate 1, as shown in FIGS. 1 and 4, two strip-shaped common electrodes 1.1 are formed parallel to each other in the length direction of the substrate. is located at the narrow portion of the inner sealing material 4°4 and extends along its length. The common electrodes 7, 7 are made of a transparent electrode material such as indium oxide. Further, a colored filter 8 is formed in the form of a band over the entire surface of both common electrodes 7, 2 except for a shutter window to be described later, and the gap aE between both common electrodes 7, 7. This colored filter 8 defines the light transmitting area of the shutter part in the SMON electrodes 7, 7, and the common electrode 71 is
For example, rectangular shutter windows 9 (portions where the common electrodes 7, 7 come out) 9 are formed in the light transmitting region. These shutter windows 9 . . . , 9 . Each of the shutter windows 9 . . . , 9 . . . has a shape and size to define a light transmission area. Further, the colored filter 8 has a dyed layer made of casein or the like dyed with an azo dye or a triphenyl dye, such as Nippon Ka Kuwa Co., Ltd., KAYANOL, MiLLlmg BLa.
K VLG (M) Dyed with methane or mixed with pigment in an insulating layer made of polymeric material, N
The color of the color filter is black or a color that matches the light absorption wavelength band of the dye to the wavelength of the light from the light source. In this way, the portions of the common electrodes 7, 7 covered with the colored filters 8 are blocked from transmitting light, and the light is transmitted only through the portions of the shutter windows 9, .

Note that 10 in the figure is an alignment film formed using the colored filter 8.

The inner surface of the segment substrate 2 is shown in FIG.

As shown in FIGS. 3 and 5, the inner sealing material 4,
A large number of segment electrodes 11..., 1
1... are the shutter windows 9..., 9 of the common board 1.
The segment electrodes 11 in one row are arranged in two rows along the length direction of the sealing material corresponding to the segment electrodes 11 in one row.
. . , and segment electrodes 1 of the other column are commonly connected to the connecting electrodes 12 . On both sides of the inner surface of the segment substrate 2, a large number of lead electrodes 13 . . . , 13 . . . lead out from the segment electrodes 11 . , 13 . . . , a large number of terminals 11L424 . . . , 14 . . . are arranged in an array. Each of these electrodes 1..., 11..., 12...,
IJ...

13... and 14..., 14... are made of a transparent electrode material such as indium oxide. The entire portion of the inner surface of the segment substrate 1 located in the narrow portion between the inner sealing materials 4 and 4, excluding the shutter window to be described later (segment electrodes 11 . . . ).

11..., connection electrode 12... and lead electrode 13
....

13... and the inner surface of the segment board 2).

A band-shaped colored filter 15 is formed to cover these. This colored filter 15 has segment electrodes 11...
. , 11 . . . defines the light transmission area of the shutter portion in each segment electrode 11 . . . , 11 .
Shaft window (segment electrode 11) which is a light transmitting area for each
..., 11... is derived) 16..., 16
... is formed, and the inner surface of the segment substrate covered with the colored filter 15 other than the shutter window is blocked from transmitting light. This shirt window 16.-, J6..
The electrodes are arranged in the segment electrodes 11 . . . , 11 . . . facing the shutter windows 9 .
. . . is a shutter window 9 for defining a light transmission area.
..., 9... are formed to have the same shape and size. Further, the colored filter 15 is formed to extend from both ends of the narrow portion of the inner sealing material 4.4 to the inner surface of the segment substrate 2 on which the test electrodes are formed. The colored filter 15, like the colored filter 8 of the common substrate 1, is formed by dyeing the layer to be dyed, or by coloring the insulating layer with a pigment and forming a round shape. Note that 17 in the figure is an alignment film formed to cover the colored filter 15.

Thus, the common electrode 7° 1 of the common substrate 1 and the shutter windows 9 . . . , 9 . . . and the segment substrate 2
segment electrodes 11..., 11... and shutter windows 16 of the same shape and size as the shutter windows 9-, 9...
. . , 16 . . . located opposite each other, and a liquid crystal LC filled in the narrow part between the inner sealing materials 4, 4.
Accordingly, one set of shutter parts is made up of stones. A large number of shutter parts are arranged between the inner sealing material 4.4.
They are arranged in rows. This shutter section is provided with a shutter window 9 formed of a colored filter 8 on the light incidence side (:!mon board 1 side), and a shutter window 9 formed of a colored filter 15 on the light exit side (segment board 2 side). Shatta window 16
is provided, and the shutter window 9 defines a light transmission area on the incident side, and the shutter window 16 defines a light transmission area on the exit side.

The liquid crystal shutter configured in this manner is provided in an optical recording section of an optical writing printer. In this case, the liquid crystal shutter is arranged facing the light source with the common substrate 1 on the light incidence side. In addition, the common electrodes 7, 7 of the common board 1 and the segment board 2
A shutter drive circuit and a connection line (not shown) are connected to the terminal electrodes 14 . . . , 14 . . . , respectively. Then, in response to a signal from the shutter drive circuit, a voltage is applied between the segment electrodes 11..., 11... and common electrodes 7, 7 in each shutter portion to cause the liquid crystal LC to behave, and each shutter selectively ``open'' and ``close'' the sections. The light from the light source passes through the "open" shutter section, and the light does not pass through the "closed" shutter section, and the drums II are formed in line on the photosensitive drum according to the opening and closing of each shutter section. be done.

In the shutter section in the "open" state, light from the light source passes through the common electrode 1 of the common substrate 1 and the shutter window 9, and enters into the liquid crystal LC between the inner seal members 4, 4. In this case, the light is absorbed and blocked by the colored filter 8 in areas other than the shutter window 9 and does not pass therethrough, and the light passes through the shutter window 9 with a transmission area corresponding to its size and shape. Next, the light passes through the shutter window 16 of the segment substrate 2 and the segment electrode 11 from the liquid crystal LC and is emitted to the outside. In this case, the light is absorbed and cut off by the colored filter 15 and does not pass through the portions other than the shutter window 16, and the light passes through the shutter window 16 with a transmission area corresponding to the size and shape of the window. That is, when the light passes through the inside of the liquid crystal LC, it becomes scattered light and becomes spread out more than the transmission area of the shutter window 9. However, the light is coming from the shattered window 16.
As the light passes through the shutter window 16, the portion that spreads due to the scattering of the light is cut by a colored filter 15 that covers the area other than the shutter window 16, and the light passes only through the transmission area defined by the shutter window 16. That is, light leakage can be prevented. Therefore, a dot image with a clear outline having a size and shape corresponding to the transmission area of the shutter window 16 is formed on the surface of the photosensitive drum. Therefore, the entire liquid crystal shutter is placed on the photosensitive drum.
An image in which dot images with sharp contrast are lined up can be formed. This allows the optical writing printer to form high quality images.

In this liquid crystal shutter, colored filters 8 and 15 are formed on both the segment substrate 1 and the common substrate 2, respectively, as light shielding members that define the light transmission area of the shutter portion. The colored filters 8, 15 are formed by applying a layer to be dyed in the air, subjecting the layer to a dyeing process, and then dyeing the layer with a dye.

On the other hand, when gold MM is used as the light shielding member, this metal film is formed inside a vacuum chamber by a process such as vapor deposition or sputtering. Comparing the two, it can be seen that the colored filter 8.15 can be formed into a round shape in an open atmosphere and is easier to form than the metal film. That is, in the liquid crystal shutter of the present invention, the light shielding member can be easily formed and has good manufacturability.

FIG. 6 shows an enlarged view of the shutter section of a liquid crystal shutter in another embodiment, and the same parts as in FIG. 1 are given the same reference numerals. In the liquid crystal shutter of this embodiment, colored filters are formed on the outer surface of each substrate. That is, the common electrodes 7, 7 and the alignment film 10 are provided on the inner surface of the common substrate 1.
Segment electrodes 11 are provided on the inner surface of the segment substrate 2.
, 11 . . . and the alignment film 17 is formed.

A colored filter 8 is formed on the outer surface of the common substrate 1, and the colored filter 8 has shutter windows 9..., 9...
A colored filter 15 is formed on the outer surface of the segment substrate 2, and shutter windows 16 of the same shape and size as the shutter windows 9 are formed on the colored filter 15. ....

It forms 16... When colored filter gold is formed on the outer surface of each substrate in this way, the following effects can be obtained in manufacturing a liquid crystal shutter.

A cell is manufactured by bonding side substrates 1 and 2 with a sealant and sealing liquid crystal between the side substrates. This liquid crystal cell is tested for light response transmittance and the like, and colored filters 8 and 15 are formed on the outer surface of each substrate 1 and 2 in cells that are found to be non-defective as a result of this test. That is, since cells can be calibrated before forming colored filters, there is no need to waste forming colored filters on defective cells.

The liquid crystal shutter in each of the embodiments described above has the shutter windows 9..., 9... on the common board 1 side and the shutter windows 16..., 16... on the segment board 2@ of the same size.
! Although the windows are formed with a diameter of 100 mm, the present invention is not limited to this, and both shaft windows may be formed with different sizes. In FIGS. 7 and 8, windows with different sizes are formed. An embodiment of the liquid crystal shutter of the present invention is shown.

FIG. 7 shows a shutter section of a liquid crystal shutter corresponding to that in FIG. 1, and the basic configuration shown in FIG. 7 is the same as that in FIG. 1. In this embodiment, a shutter window 9 formed by a colored filter 8 on the inner surface of the common substrate 1...
, 9..., the shutter windows 16.-, 16.
There are nine similar shapes and small sizes of...

FIG. 8 shows a shutter portion of a liquid crystal shutter corresponding to FIG. 6, and its basic configuration is the same as that in FIG. 6. In this embodiment, while the shutter windows 9 . . . , 9 . ..., 16... are similar in size and smaller.

In the configurations shown in FIGS. 7 and 8, the shutter windows 17 . . . , 17 .
Positioning can be performed with a margin within the size range of . Therefore, the positioning of the shutter window of the side substrate 1.2 is facilitated, and the formation of the shutter window and the assembly of each substrate are facilitated.

〔Effect of the invention〕

As explained above, according to the liquid crystal shutter of the present invention, colored filters are formed on each of the pair of substrates as light shielding members,
Since the shutter window is formed using these colored filters, it is possible to prevent light leakage at the shutter part and obtain an image with high contrast. Good quality and good quality.

[Brief explanation of drawings]

1 to 5 show an embodiment of the liquid crystal shutter of the present invention. FIG. 1 is an enlarged sectional view of the shutter portion, FIG. 2 is a cross-sectional view of the liquid crystal shutter, and FIG. 3 is a segment view. 4 is a plan view showing the inner surface of the common board, FIG. 5 is a plan view showing an enlarged view of the main parts of the segment board, and FIGS. 6 to 8 are different from each other. FIG. 2 is a cross-sectional view showing the shutter portion of the liquid crystal shutter in the embodiment. 1... Common board, 2... Segment board, 7...
- Common electrode, 8... colored filter, 9... shutter window, 11... segment electrode, 15... colored filter, 16... shutter window, LC... several items. Applicant's agent and patent attorney Takehiko Suzue Figure 5 Figure 6 Figure 8

Claims (3)

[Claims] (1) A segment substrate and a common substrate placed opposite each other with a liquid crystal in between, a segment electrode made of a transparent electrode formed on the inner surface of the segment substrate, and a segment electrode formed on the inner surface of the common substrate that transmits light together with the segment electrode. and a common electrode made of a transparent electrode constituting a shutter section for controlling the light, and colored filters provided on the segment substrate and the common substrate, respectively, and defining light transmission areas in the segment electrode and the common electrode. Features a liquid crystal shutter. (2) The liquid crystal shutter according to claim 1, wherein the colored filter is a layer to be dyed. (3) The liquid crystal shutter according to claim 1, wherein the colored filter is an insulating layer mixed with a pigment.