JPS62269116A - Liquid crystal element - Google Patents

Abstract

PURPOSE:To obtain a liquid crystal element having an excellent space factor and good quality at a low cost with a simple stage even in the case of high resolution and a large number of electrodes by contg. a flexible circuit board, transparent board having rigidity and liquid crystal material. CONSTITUTION:A patterned conductor film 3 consisting of copper (indium oxide is used in a region 5 facing the circuit board) as stock is formed on the surface of the flexible circuit board 1 for which a transparent base film is used. A transparent electrode is formed on one surface of the thick-walled transparent plastic board 2. Two sheets of the boards 1, 2 face each other apart at a specified space formed therebetween by spacers 7 which are glass fibers. A ferroelectric liquid crystal material 8 is filled into the space. The flexible circuit board 1 is flexible except in the region 5 facing the rigid plastic board 2 which acts as a reinforcing member as well. The form of packaging by folding and superposing on the rear of a shutter array region is possible. The liquid crystal element having the excellent space factor with substantially no blank parts at the periphery and good quality is thus obtd.

Description

[Detailed description of the invention] [Industrial application field] The present invention relates to the structure of a liquid crystal element.

[Conventional technology]

Liquid crystal displays that utilize the electro-optic and thermo-optic effects of liquid crystals are widely used. Further, development of electrophotographic liquid crystal printers using liquid crystal optical shutter arrays is progressing. As described above, the liquid crystal display spring 11 and the liquid crystal optical shutter have already been commercialized, but research and development is still actively being carried out to increase the display capacity of the display and to improve the resolution of the optical shutter. . Of course, it is necessary to improve the liquid crystal operation in order to increase the capacity of liquid crystal elements, but what is more problematic in terms of practical application is the increase in the number of electrodes in liquid crystal elements and the increase in resolution. , a method of connection with an external drive circuit.

Hereinafter, for the sake of simplicity, we will explain the conventional technology and Honmaru Akira 6''C by taking as an example a liquid crystal optical shutter array used in liquid crystal printers, etc. Fig. 3 shows the structure of the connecting part of a conventional liquid crystal optical shutter array. It is a cross-sectional view. In the third stage, 31 and 32 (two glass substrates with a liquid crystal material 30 sandwiched between them), transparent electrodes 33 and 34 are formed on their inner surfaces. 735 is a flexible circuit board having a patterned conductor film 36 corresponding to the transparent electrode 34 of the liquid crystal optical shutter array.

Although not shown in the figure, normally some of the circuit elements (so-called IC chips, etc.) constituting the drive circuit are mounted on the flexible circuit board 35, or the flexible circuit board 35 is mounted on the printed circuit board on which the circuit elements are mounted. It is configured by connecting.

One major problem with such conventional liquid crystal optical shutter arrays is that the transparent electrode 3 of the liquid crystal optical shutter array
4 and the corresponding conductor 36 of the flexible circuit board 35
Conventionally, an overlapping part is provided as shown in Fig. 3, and the transparent electrode 34 and the conductor 36 are opposed to each other at that part, and the transparent electrode 34 and the conductor 36 are directly pressed together mechanically, or by using an anisotropic conductive rubber. Structures were used, such as sandwiching and pressing materials such as the above, soldering using methods such as infrared heating, or thermocompression bonding via an adhesive anisotropic conductive sheet. FIG. 3 shows an adhesive anisotropic conductive sheet 37.
Here is an example using .

Regarding conventional electrode connection technology, for example, "electronic materials"
(Industrial Survey Interest) September 1985 issue, pages 49 to 58
It is introduced throughout the page.

[Problem that the invention seeks to solve]

Among the conventional liquid crystal elements mentioned above, this is the most precise electrode pin.
The one that can be used in Sochi uses a structure that uses thermocompression bonding via an adhesive anisotropic conductive sheet. According to this structure, it is currently possible to connect electrodes with a resolution of approximately 5 electrodes per wire.

However, for optical shutter arrays for printers,
A high resolution of about 16 lines/■- is required.

Even if this number of electrodes is divided into two parts above and below the shutter element and connected to the flexible circuit, the resolution, that is, the electrode pitch, will be finer than the above-mentioned conventional structure.

Further, a shutter array for a printer is required to have a length of at least about 210 am, which corresponds to the short side length of an A4 size sheet. However, in the case of connections in conventional liquid crystal elements, it is not possible to increase the connection length beyond a certain level due to differences in expansion coefficients between the two substrates due to differences in the material of the shutter array substrate and the material of the flexible circuit board. becomes shorter as the electrode pattern becomes more precise. In the structure using the adhesive anisotropic conductive sheet described above, the connection length is limited to about 100 lengths in a 5 electrode pattern.

On the other hand, in order to reduce the number of electrodes connected to the flexible circuit board, there is a method of building or mounting a portion of the drive circuit elements around the board of the shutter array. It becomes wider and the space factor decreases.

The purpose of the present invention is to
The object of the present invention is to provide a high-quality liquid crystal element with an excellent space factor of 2 at a low cost and without the need for a complicated process of electrode connection.

[Means for solving problems]

The liquid crystal element of the present invention is a flexible circuit board in which a patterned conductor film is formed on a base film having a transparent portion on at least a portion thereof, and a transparent electrode is formed on at least a portion of the transparent portion of the conductor film. and a rigid transparent substrate having a transparent electrode on at least a portion thereof and fixed to a portion of the flexible circuit board including at least a portion of the transparent portion thereof so as to face the portion thereof with a spacer interposed therebetween; and a liquid crystal material filled in the gap between the transparent substrates.

(Function) In the liquid crystal element of the present invention, since one electrode substrate constituting the liquid crystal element is a flexible circuit board, the driving circuit element is mounted on this substrate, for example, using a tab (TAB).
Therefore, there is no need for complicated processes that cause high costs, such as connecting a large number of high-definition display electrodes to electrodes on a drive circuit board in an optical shutter array for a printer. .

In addition, the flexible circuit board other than the part where the counter board as a reinforcing member is attached can be easily bent and curved, and by adopting this mounting form, it is possible to produce a high-quality liquid crystal element with an excellent space factor with little blank space. is obtained.

〔Example〕

An embodiment of the liquid crystal element of the present invention will be described in detail below with reference to the drawings.

FIG. 1 is a schematic plan view of a liquid crystal element of the present invention, and FIG. 2 is a cross-sectional view along line AA' shown in FIG. 1 and 2, reference numeral 1 is a flexible circuit board using a transparent base film, the surface of which is covered with copper (substrate facing area 5).
A patterned conductor 115I3 is formed using indium oxide instead of copper (in order to avoid complication of the diagram, only a portion of the conductor film 3 is shown in FIG. (It is omitted in the eyes). 2 is a thick transparent plastic substrate with a transparent electrode 4 formed on one surface, and 5 is an area where the two transparent substrates face each other.

Note that the transparent electrode 4 is transferred to the electrode on the opposing substrate 1 inside the region 5. 6 is two boards 1.2
This is the adhesive layer that fixes the The two substrates 1.2 face each other with a certain gap formed by an impasser 7 made of glass fiber, and a ferroelectric liquid crystal material 8 is placed in the gap.
is filled.

Note that a portion of the conductive film 3 located inside the region 5 is a transparent electrode made of indium oxide. Also,
The flexible circuit board 1 includes an IC that constitutes a drive circuit.
A chip 11 is mounted and a drive circuit is configured on the flexible circuit board 1.

The liquid crystal element constructed in this manner has the same optical shutter performance as a ferroelectric liquid crystal element with a conventional structure, and
Driving is possible without requiring a complicated process of connecting a large number of electrodes between the shutter array element and the driving circuit. In addition, the flexible circuit board 1 is flexible except for the board facing area 5 that faces the rigid plastic board 2 that also serves as a reinforcing member, and can be mounted in a manner such as folded over behind the shutter array area. In this way, it is possible to obtain a high-quality liquid crystal element with an excellent space factor and almost no margins around the periphery.

It goes without saying that the materials used in this example do not limit the present invention in any way.

〔Effect of the invention〕

As described above, according to the present invention, it is possible to obtain a high-quality liquid crystal element with an excellent space factor, which can be manufactured using simple steps and at a low cost even in the case of high resolution and a large number of electrodes.

[Brief explanation of the drawing]

Fig. 1 is a plan view showing the structure of an embodiment of the liquid crystal element of the present invention, Fig. 2 is a sectional view taken along the line AA'' shown in Fig. 1, and Fig. 3 is a diagram showing the connection part with an external circuit in a conventional liquid crystal element. It is a sectional view showing the structure. In the figure, l is a flexible circuit board using a transparent base film, 2 is a plastic substrate, 3.4 is a patterned conductive film, 5 is a substrate facing area, and 6 is an adhesive. layer, 7 is a spacer, 8 is a liquid crystal material, 11 is an IC chip,
30 is a liquid crystal material, 31.32 is a glass substrate, 33.34
35 is a transparent electrode, 35 is a flexible circuit board, 36 is a patterned conductor, and 37 is an adhesive anisotropic conductive sheet. Figure 1: Full-time reference level Figure 2: Figure 3

Claims (1)

[Claims] A flexible circuit board having a patterned conductor film formed on a base film having a transparent portion on at least a portion thereof, and having a transparent electrode on at least a portion of the transparent portion of the conductor film; a rigid transparent substrate having an electrode and fixed so as to face at least a portion of the transparent portion of the flexible circuit board via a spacer; and a gap between the flexible circuit board and the transparent substrate is filled. A liquid crystal element comprising a liquid crystal material.