KR940006296B1 - Lcd of plasma addressing form - Google Patents

Abstract

The plasma address-form liquid crystal display device wherein a front and back plate are arranged perpendicular to each other, a plurality of a first electrode having a strip shape, liquid crystal layer and dielectric layer are sequentially formed on the front plate, a plurality of a second electrode, which forms discharging space having a predetermined interval and height, are formed parallel to each other between the dielectric layer and back plate, a strip-shape insulating layer is inserted between second electrode and dielectric layer, realizes high-density image.

Description

Plasma Address Type Liquid Crystal Display Device

1 is a schematic exploded perspective view of a conventional plasma address type liquid crystal display device.

FIG. 2 is a partially enlarged cross-sectional view of the display device shown in FIG.

3 is a schematic cross-sectional view of a plasma address type liquid crystal display device according to the present invention.

4 is a waveform diagram of a driving voltage pulse applied to a liquid crystal display device according to the present invention.

The present invention relates to a flat panel display device of a plasma address type composite configuration.

The display device includes a conventional cathode ray tube using high-speed electron beams, a fluorescent display tube using low-speed electron beams, a plasma display device using gas discharge, a so-called E.L display device using an electroluminescent effect, and a liquid crystal display using an electro-optical effect. There are many different kinds of devices. These types of display devices are selectively applied according to their characteristics because they have different functions and structural characteristics.

Common to these display devices is that they visualize electrical image signals or data signals, etc., which are structurally and functionally improved in various aspects, respectively.

Recently, the development trend of the display device is aimed at a display device having a thin screen as high as possible with a large screen of high definition due to the demand of a large amount of public information display medium and the appearance of a high definition so-called HDTV on a large screen.

In response to the development trend, a new type of matrix type display device in which a plasma discharge device and an electro-optical device, ie, a liquid crystal display device are combined, has been recently developed. The display apparatus is a method of addressing one line by plasma discharge. As shown in FIG. 1, an array structure in which a plurality of stripe-shaped pixel electrodes 14 are arranged in parallel is arranged in the liquid crystal shutter unit 10 and the liquid crystal. The plasma discharge unit 20 provided with a plurality of unit discharge lines 21 in a direction orthogonal to the stripe-shaped pixel electrodes 14 of the shutter unit 10 is overlapped with each other. 2, the liquid crystal shutter portion 10 is first injected with liquid crystals 113 between two transparent substrates 12 and 13, and a stripe is formed on the inner surface of the front side substrate 12. The upper pixel electrode 14 is formed. In the discharge unit 20, a plurality of grooves (GROOVE) 24 forming a discharge line 21 in a direction orthogonal to the stripe pixel are formed on one base plate 25 in parallel with each other. A pair of electrodes 22 and 23 are provided on both sides of the bottom surface of 24. In this state, the base plate 25 is tightly fixed to the lower substrate 13 of the liquid crystal shutter unit 10 so that the groove 24 forms a closed discharge space, thereby filling the discharge gas. It becomes.

In the structure as described above, the liquid crystal shutter unit 10 mainly includes a stripe pixel 11 and a plasma scan line 21 to be described later by applying a data signal sequentially to the pixels on the stripe. It allows selective passage of dot light. A scan signal is instantaneously applied to the plasma discharge unit 20 to exert a linear DC discharge light on the selected scan line 21. Accordingly, a data signal is applied to the liquid crystal shutter unit 10 in the state where the linear discharge light is exerted on the discharge line 21 on one side by the scan signal, that is, in the electrically conductive state, so that the discharge line ( When one of the stripe pixels orthogonal to 21) is selected, an electric field is formed at the intersections thereof, and rearrangement of the liquid crystal layers positioned therein occurs. Therefore, the light from the background light generating device (not shown) located on the back of the discharge portion is made (that is, to form one flash point).

Such a display device is a unique type of flat panel display device that orients liquid crystals to pixel electrodes and discharge lines, and has the following disadvantages. As described above, since the discharge part is formed on the groove 24 formed on the base plate and a separate material sealing the same, for example, the lower substrate 13 of the liquid crystal shutter part as described above, the manufacturing process is performed. There are very difficult drawbacks. This is especially true since the lower substrate 13 of the liquid crystal display must be assisted to obtain one sealed discharge space. In such a case, if leakage of the discharge space is caused, the repair is virtually impossible, resulting in the disadvantage of having to dispose of the product itself.

SUMMARY OF THE INVENTION An object of the present invention is to provide a flat panel display device including a plasma discharge tube and an electro-optical device which can improve the conventional problems listed above.

In order to achieve the above object, the present invention, the front plate and the back plate is arranged at a predetermined interval, the first electrode, the liquid crystal layer and the dielectric layer in a plurality of parallel stripes to the front plate side are sequentially installed, the dielectric layer and the back plate A plurality of second electrodes which are orthogonal to the first electrode and partition a stripe-shaped discharge space having a predetermined interval and a height between the dielectric layer and the back plate are formed in parallel with each other, and between the second electrode and the dielectric layer. The feature is that a stripe-shaped insulating layer is provided which insulates the second electrode and the dielectric layer.

In the liquid crystal display of the present invention as described above, the second electrodes are formed to face each other with adjacent electrodes while forming a stripe-shaped discharge space between the dielectric layer and the back plate. It has a structural feature capable of discharging with the second electrode.

Accordingly, in the method of driving the liquid crystal display device of the present invention for driving the liquid crystal display device of the present invention, the front plate and the back plate are arranged at predetermined intervals, and the first electrode, the liquid crystal layer, and the dielectric layer in a plurality of parallel stripes to the front plate side. The second electrodes are sequentially provided, and a plurality of second electrodes which are orthogonal to the first electrode are formed between the dielectric layer and the back plate to form a stripe discharge space having a predetermined interval and a height between the dielectric layer and the back plate. In the method of driving a plasma address type liquid crystal display device having a stripe-shaped insulating layer insulated between the second electrode and the dielectric layer between the second electrode and the dielectric layer, the second electrode is the center. The preceding discharge occurs by applying a voltage of a predetermined potential between the pre-secondary electrodes provided at the front end thereof, The discharge on the next line following the preceding discharge is applied with a predetermined voltage to the second electrode in the center and the second electrode after which the next discharge occurs and at the same time, the pre-second electrode and the second center in the center are discharged. It is characterized by changing the potential so that the potential below the discharge sustaining voltage is maintained between the electrodes so that the preceding discharge is stopped so that the discharge occurs sequentially between adjacent second electrodes as a whole.

The characteristic of the driving method of the present invention contributes to two discharges together with another second electrode before and after one second electrode, and one electrode serves as a cathode and an anode by sequentially applied pulse voltages. Alternately, other adjacent electrodes serve as anodes or cathodes corresponding to the electrodes in the center thereof.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a schematic cross-sectional view of the liquid crystal display device of the plasma addressing method according to the present invention, which is divided into a liquid crystal shutter unit 100 and a plasma addressing unit 200, and after the addressing unit 200. On the side, a background light generator (not shown) is provided. The transparent front plate 120 and the back plate 250 are disposed at predetermined intervals to protect the functional layer located therebetween. A plurality of stripe-shaped first electrodes 140 are formed in parallel on the front plate 120, and the liquid crystal layer 160 and the dielectric layer 130 are sequentially provided in contact with the front plate 120. The stripe-shaped insulating layer 220 and the second electrode 230 are arranged in parallel to the opposite side of the liquid crystal layer 160 with the dielectric layer 130 as the center. The insulating layer 220 and the second electrode 230 are arranged in a direction orthogonal to the first electrode 140, and have a stripe shape having a predetermined interval and a height between the dielectric layer 130 and the back plate 250. The discharge space 210 is defined.

As described above, the liquid crystal display device of the present invention is configured such that each of the second electrodes alternately functions as a cathode and an anode due to the structural characteristics of the plasma addressing unit. The electrodes of the two sides face each other through the discharge space to enable direct-current discharge. That is, the second electrode serves as a partition wall that partitions the discharge space together with the corresponding insulating layer, and at the same time, it can generate a direct current discharge with another second electrode before and after facing the discharge space toward the center.

The driving method of the liquid crystal display device of the plasma addressing method of the present invention is as follows.

The data signal is written (input) to the first electrode of the liquid crystal shutter unit, and the scan signal is written to the second electrode of the plasma addressing unit. When scanning is performed from the first line, the corresponding discharge line (stripe phase) A pulsed voltage for discharging is applied between both second electrodes adjacent to the unit discharge space). This causes a discharge and forms an electric field in the liquid crystal in the discharge line direction by the discharge, so that the liquid crystal at the intersection with the first electrode to which data is written is excited and oriented in a predetermined direction. In the step of discharging to the next discharge line, the pulsed voltage of the predetermined potential is applied next between the second electrode on the side of the second electrode which contributed to the first discharge and the next new electrode next to the discharge space for discharge. Discharge occurs.

At the same time, an erase pulse for terminating the first discharge is written to stop the preceding discharge and lead to the next new discharge. In other words, when a pulse as shown in Figs. 4a) and 4b) is written to the second electrodes formed on both sides of one discharge space, the preceding discharge is started and maintained for the period A. At this time, one of the electrodes for the preceding discharge is maintained at a voltage higher than the bias voltage to become an anode, and the latter (center) electrode is applied to a voltage less than the bias voltage to become a cathode. Subsequently, in the step of discharging to the next line, the voltage to the center electrode rises above the bias voltage and the potential difference with the previous electrode drops, thus ending the preceding discharge, and at the same time, the electrode at the end, that is, A voltage below the bias voltage is applied to the new electrode in the discharge space so that the next discharge occurs due to a large potential difference with the center electrode.

Therefore, the liquid crystal display device of the present invention is that the second electrode alternately performs the role of the anode and the cathode so that continuous line discharge is possible, and the structural characteristics of the liquid crystal display device compared to the conventional plasma addressing type liquid crystal display device The number of (second) electrodes for is reduced by half. Therefore, the gap between the discharge lines can be further narrowed, so that an image of density can be realized. On the other hand, since the discharge space is formed by the laminated structure of the insulating layer and the second electrode, there is no difficulty in processing such as forming grooves on the back plate as in the prior art.

Claims (2)

The front plate and the back plate are disposed to face each other, and a plurality of parallel first electrodes on the front plate side, a front liquid crystal layer, and a dielectric layer are sequentially provided, and between the dielectric layer and the back plate are disposed with respect to the first electrode. A plurality of second electrodes which are orthogonal to form a stripe discharge space having a predetermined interval and a height between the dielectric layer and the back plate are formed in parallel, and a stripe insulates the second electrode and the dielectric layer between the second electrode and the dielectric layer. A plasma address type liquid crystal display device comprising a phase insulating layer interposed therebetween. The front plate and the back plate are disposed to face each other, and the first electrode, the liquid crystal layer, and the dielectric layer, which are arranged in parallel to the front plate side, are sequentially provided, and are orthogonal to the first electrode between the dielectric layer and the back plate. And a plurality of second electrodes partitioning a stripe-shaped discharge space in parallel between the dielectric layer and the back plate, and a plasma having a stripe-shaped insulating layer interposed between the second electrode and the dielectric layer to insulate the second electrode and the dielectric layer. A method of driving an address type liquid crystal display device, comprising: applying a voltage of a potential between pre-second electrodes provided at a front end thereof with the second electrode as a center to cause a preceding discharge, and causing the preceding discharge The discharge on the next line is followed by applying a voltage to the central second electrode and the second electrode In the plasma addressing method, a negative discharge occurs and a potential is changed between the pre-second electrode and the center second electrode so that a potential below the discharge sustain voltage is maintained so that the preceding discharge is stopped. A method of driving a liquid crystal display device.