DE3006052C2 - Liquid crystal display cell - Google Patents

Description

35

The invention relates to a liquid crystal display cell as specified in the preamble of the main claim Genus that has improved readability

In general, show the liquid crystal display cells with twisted nematic phase, the field effect ab- can be operated pending, because of the twisted arrangement of the liquid crystal molecules one of the Reading angle or the viewing angle dependent behavior. The reading angle varies as a function on the control voltage applied to the liquid crystal display cell. One observes a remarkable one Reading angle dependence when the display device has a signal with a lower effective voltage is controlled.

According to DE-OS 28 47 320, a field-effect controllable liquid crystal display cell with a twisted nematic phase is already known, which to improve the display contrast a fiber board with a plurality of optical fibers whose axes are perpendicular to the plane of the liquid crystal layer.

DE-OS 27 11 015 also discloses an electro-optical display device of the type mentioned at the beginning Type, as it is used, for example, for wristwatches, which is provided with a front-side fiber optic cell plate with light-conducting fibers running perpendicular to the display surface, thus also in the tilted state of the display device, the full display area can be read.

The object of the present invention now exists therein, in a liquid crystal display cell of the type specified in the preamble of the main claim to increase the brightness of the display without sacrificing the edge contrast and thus an improvement in the To achieve reading properties.

This object is now achieved by the characterizing features of the liquid crystal display cell according to the main claim, that is to say in that the The configuration and the arrangement of the open core end of the optical fibers are substantially Jem, respectively associated picture element, the do-ch the associated transparent front electrode and the associated rear electrode is defined.

According to a preferred embodiment of the invention, the liquid crystal display cell has a transparent ones disposed between the optical fiber plate and the transparent front electrode Plate that serves as a reinforcement layer

From US-PS 29 83 835 and DE-OS 25 41 003 it is already known the spatial position of optical Adapt fibers to the image points to be imaged.

The inventive adaptation of both the configuration and the arrangement of the open Core end of the optical fibers to the respectively assigned picture element, it is possible to adjust the brightness to increase the display quite considerably, without the optical through the enlargement of the open core ends Fibers a reduction in the edge contrast is caused.

The invention is explained in more detail below with reference to the drawings Drawings shows

F i g. 1 is a perspective illustration to illustrate the reading angle;

F i g. FIG. 2 shows a schematic representation to illustrate the behavior of FIG conventional liquid crystal display cells with a twisted nematic phase that are field effect dependent can be operated;

F i g. 3 is a schematic sectional view of the basic structure of the known liquid crystal display cell twisted nematic phase that can be operated depending on the field effect;

4 and 5 enlarged sectional views of a detail of the FIG. 3 liquid crystal display cell;

F i g. 6 (A) and 6 (B) are schematic plan views showing the relative positions of the picture element and the optical Clarify fibers in conventional cells;

F i g. 7 (A) and 7 (B) are schematic plan views showing the relative arrangements of the picture element and the reproduce optical fibers in one embodiment of the invention; and

8 shows an enlarged sectional view of a detail of an embodiment of the invention Liquid crystal display cell with a twisted nematic phase that can be operated depending on the field effect.

First, with reference to FIGS. 1 explains the parameters of the θ and Φ of the reading direction

The perpendicular coordinates X and K define the display surface of a liquid crystal display device 1 such that the X-axis is parallel to the main axis of the liquid crystal molecules adjacent to a substrate in the state that no electric field is applied to the device is. The Z axis defines the direction perpendicular to the display surface. The angle θ stands for the angle between the reading direction vector Kund of the axis Z, while the angle Φ the angle between the X axis and the projection of the reading vector purchase the coordinates

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The F i g. 2 illustrates the behavior of the conventional liquid crystal display cell, which is dependent on the reading direction, with a twisted Nemaüscher phase, which can be operated as a function of the field effect. This Fig. 2 b illustrates the display contrast ratio, which varies depending on the angle Φ at constant *.; ^ Wmkei θ (θ = 20 °), curve 1 showing the state when the effective value of the applied voltage is 2 ^ volts , curve 2 illustrates the state when the effective value of the applied voltage 3, U V'ol! and curve 3 shows the state where the effective value of the applied voltage is 6.0 volts

More precisely, the area surrounded by the curve defines the area of good display contrast, while outside the area defined by the curve, no good contrast can be found

It is from the fig. 2 clearly shows that the reading angle range decreases with decreasing applied voltage. Furthermore, a good contrast is achieved in a certain direction of the coordinate plane XY.

The in the F i g. The behavior shown in 2 was determined as follows. A liquid crystal display cell is used which contains a mixture of liquid crystal Schiff bases MBBA, EBBA and BBAB as liquid crystal preparation, the liquid crystal layer having a thickness of 6 μm no electric field is applied below 5 °. The transparent electrode consists of In ₂ Oi, while the orientation layer comprises a SiOr layer which has been provided with micro-grooves by rubbing. The control voltage used comprises a rectangular alternating voltage signal with a frequency of 32 Hz.

The dependence of the display contrast on the angle Φ becomes large when the liquid crystal display cell with a twisted nematic phase, which can be operated as a function of the field effect, is operated in multiplex operation or dynamically. This results from the fact that the effective voltage decreases as the multiplex ratio increases

To reduce the disadvantages addressed above, it has already been proposed in DE-OS 28 47 320, the front substrate of the liquid crystal display cell to provide a fiber plate consisting of a plurality of optical fibers, the axes of which run perpendicular to the liquid crystal layer. The fiberboard thus has a layer opposite to the liquid crystal layer Surface which is essentially parallel to the liquid crystal layer. Above the fiberboard a front polarizer is arranged

To read the display, the observer 2 is located in front of the liquid crystal display cell twisted nematic phase, which can be operated depending on the field effect, which has a front polarizer 3, an optical fiber plate 4, a transparent front electrode 5, a front orientation layer 6, a Liquid crystal layer 7, a sealing device 8, a rear orientation layer 9, a transparent one rear electrode 10, a rear glass substrate 11, a rear polarizer 12 and a reflector U comprises.

4 illustrates the optical fiber plate 4 more accurate. The reference numbers given correspond to those shown in FIG. 3 are given.

The illustrated in Fig.4 -. 'Ellen optical fiber plate 4 comprises a plurality of optical fibers whose axes are perpendicular to the layer behind the liquid crystal layer 7 run. Di? op: hihi: fiberboard 4 wmfp.Rt. an inner surface 14 which is substantially p3.s! | e! to the plane of the liquid crystal layer 7 runs

each optical fiber has a length. ', y're sufficiently larger than the radius r of the fiber, thereby making the reading angle dependence more uniform. The inner surface 14 of the fiberboard

4 is at a distance m, which corresponds to the thickness of the transparent front electrode 5 and the front orientation layer 6, from the liquid crystal layer 7, this distance preferably being less than 40 r . If the distance m is greater than 40 r, one can go through watch the fiber board 4 no picture.

The above-mentioned liquid crystal display cell described in DE-OS 28 47 320 is suitable for this purpose to make the reading angle dependency more uniform. However, on the other hand, di <* brightness becomes the Display diminishes when the open ends of the optical fibers are small. On the other hand, if the open ends of the optical fibers are large, there is a possibility that the optical fiber will stretch over the activated picture element and the non-activated picture element extends, which leads to a reduction in the Display contrast leads

The F i g. Fig. 5 illustrates the relationship between the optical fibers and the picture elements of the liquid crystal display cell; the in the F i g. 3 is shown. In the case of the FIG. The cell shown in FIG. 5 are the electrodes

5 and 10 arranged in a matrix form so that a matrix display results

More specifically, the transparent front electrode 5 comprises parallel X- line electrodes made of In ₂ O ₃ , while the transparent rear electrode 10 comprises parallel Y- line electrodes which are perpendicular to the X-line electrodes and which are also made of 1 ^ O ₃ . The crossing points of the X-line electrodes and the Y-line electrodes function as picture elements 5 '. Each optical fiber includes a core portion and a clad portion in FIG. 5, the configuration of the open end of the core section is shown under the reference number 4 ', while the reference number 4 "shows the cladding section. The front and rear orientation layers 6 and 9 consist of rubbed SiO2 layers with a thickness of about 10 nm (1000 Å ) or from SiO layers which have been formed by oblique vapor deposition. The liquid crystal layer 7 comprises cholesteric liquid crystals with positive dielectric anisotropy and long inclination or nematic liquid crystals. A preferred material is, for example, the material "E-8" from BDH Chemicals Ltd. or the material “ROTN 403” from F. Hoffmann-La Roche & Co. In the case of a see-through display device, instead of the reflector 13, a light source is arranged on the back of the rear polarizer 12.

The Γ i g. 6 (A) and * {Β) illustrate the undesirable relationship between the open core end 4 'of the optical fiber and the picture element 5'. If only a part of the open core end 4 'extends over a part of the one picture element 5', as shown in FIG. 6 (A) 'ir ' ■■■. If the open area 4 'has a size which is substantially smaller than that of the picture element 5', as shown in FIG. 6 (B)

there is a decrease in the brightness of the Advertisement.

To eliminate the above-mentioned disadvantages, the fiber board 4 is designed according to the invention such that the open core end 4 'corresponds essentially to the picture element 5', as shown in FIGS. 7 (A) and 7 (B) is shown. In this way, both the display contrast and the display brightness become clear improved.

If the open core end 4 'is relatively large, it is preferred to have a reinforcement plate 14 between the optical fiber plate 4 and the transparent front electrode 5, as shown in FIG. 8 is shown. The reinforcing plate 14 must be transparent and

have optically isotropic properties. The front polarizer 3 can be positioned between the optical fiber plate 4 and the reinforcement plate 14 may be arranged. In this case, the reinforcement plate 14 must be as possible be thin to enable a clear display and must have a thickness that is at most im is essentially identical to the diameter or the edge of the open core end 4 '. According to a Another preferred embodiment can be another reinforcement plate between the front Polarizer 3 and the optical fiber plate 4 are arranged. The reinforcement plate must be transparent be and have optically isotropic properties and is preferably made of glass.

For this purpose 4 sheets of drawings

Claims (2)

Claims; 1. Liquid crystal display cell with twisted nematic phase, which can be operated depending on the field effect, having a front polarizer, a transparent front substrate, a rear substrate, a liquid crystal layer arranged between the transparent front substrate and the rear substrate, transparent formed on the transparent front substrate front electrodes, rear electrodes formed on the rear substrate, the transparent front electrodes and the rear electrodes jointly defining picture elements for display purposes, and the transparent substrate comprising a plurality of optical fibers the axes of which are perpendicular to the plane of the liquid crystal layer and each of which have an open end opposite the liquid crystal layer, characterized in that the configuration and the arrangement of the open core end of the optical fibers essentially correspond to the respectively associated picture element correspond, which is defined by the assigned transparent front electrode (5) and ah assigned rear electrode (10). 2. Liquid crystal display cell according to claim 1, characterized in that it has one between the optical fiber plate (4) and the transparent front electrode (5) arranged transparent Plate (reinforcement plate 14) includes