DE2442650A1 - Flat display panel using direct current charge - with inter linear scanning, has perforations in cathodes divided into two groups in each case linked by slots - Google Patents

Abstract

The flat display panel has a number of anodes crossing a number of cathodes with perforations at the points of intersection. There are a number of additional anodes crossing the cathodes and facilitating the discharges. The perforations in the cathodes are divided into two groups. The first group has at least two perforations linked by slots at the points of intersection between the cathodes and the additional anodes. The second group has at least two perforations linked by slots at different points of intersections between additional anodes and cathodes. This facilitates the main discharges to be initiated in the perforations by alternate discharges in the first and second sets of slots.

Description

Flat display The invention relates to a flat display device, kirz flat display that uses direct current discharge, and in particular one Flat display that can easily be interlaced.

Conventional flat displays are illustrated with reference to FIGS. 1, 2, 3A,.

3 B, 3 C and 3 D explained in more detail.

Fig. 1 shows in p, perspective view the structure of a conventional used Flat panel display employing direct current discharge.

A transparent or translucent isolator plate is shown 1, an anode conductor 2, an insulating plate 3, one provided in the insulating plate 3 Perforation 4 to form a main discharge space, a cathode electrode or plate 5, a perforation 6 provided in the cathode plate 5, an insulating substrate 7, a channel 8 provided in the insulating substrate 7 for forming an auxiliary discharge space, an anode electrode provided for auxiliary discharge in auxiliary discharge channel 8 9, and a phosphor applied or coated in the interior of the perforation 4 10.

First, an auxiliary discharge via the cathode plate 5 and the Auxiliary discharge anode electrode 9. generated to excite a main discharge in the perforation arranged between the cathode plate 5 and the anode conductor 2 4 to facilitate.

In particular, when an auxiliary discharge is generated, charged particles or atoms at metastable energy levels which are the main discharge Space-forming perforation 4 over the perforation 6. Since the metastable atoms hit the wall of the main discharge space to generate secondary electrons, causes the penetration of particles of the metastable atoms into the main discharge space therein an increase in the electron density, thereby increasing the ignition voltage for the main discharge space is decreased.

Because of this phenomenon, it is possible to use a control or driver circuit to simplify for a flat display. In particular, based on the known Operating principle of a step discharge tube, the transfer of the auxiliary discharge can be achieved by a multiphase pulse wave.

For example, several auxiliary discharges are arranged in columns s-A node electrodes successively line-scanned with a voltage, and are synchronously arranged in lines until an auxiliary discharge is obtained Anode conductor connected to a video signal that corresponds to a low voltage, but is sufficient to trigger a main discharge, thereby displaying a desired image, is mapped or displayed. With this method, the number of for the columns of matched driver circuits provided are reduced to a few will.

As an improvement to the conventional flat display shown in FIG already specified another conventional flat panel display which is mapping or displaying an image with a large surface area and a structure according to FIGS. 2 and 3A, 3B, 3C, 3D. There are shown several an insulating substrate 7 superimposed anode conductors 2 and one the insulating substrate 7 and the anode conductors 2 covering insulating layer tl, which is why the anode conductor 2 from the insulating layer 11 are supported on the insulating substrate 7. It should be noted that sections 12 of the anode conductor 2 are exposed to the outside at main discharge spaces 13, d. H. with perforations formed in a cathode plate 5. A phosphor 10 is on a dielectric layer and the sections 12 of the anode conductor 2 surrounding applied, and a channel 14 is formed in the cathode plate 5, the with-a other channel 8 is in communication, which is an auxiliary discharge space to the main discharge space 13 educates. In this example, one auxiliary discharge controls several Main discharges (two main discharges in Fig. 2) occurring in adjacent main discharge spaces 13 are generated, which are arranged in the longitudinal direction of a cathode plate 5, so that the number of auxiliary discharge anode electrodes 9 ge genliber based on Fig. 1 described conventional flat display can be reduced by half can.

However, the conventional flat displays described have disadvantages. First is interlaced scanning for imaging or displaying one of a kind image obtainable with an ordinary television signal is extremely complicated and cumbersome. Since, in particular, the ordinary television signal has a horizontal blanking interval of about 10 at a horizontal scan period of about 50 ps, it is around one To be able to perform effective interlace scanning, it is desirable that a transmission pulse for auxiliary discharge, the one cathode involved in the display of an image assigned, has a large pulse width, whereas another transmission pulse, assigned to another cathode that is interlaced, has a smaller pulse width than the horizontal blanking interval. The cathodes, which are intended to display an image and an interlaced scan are subject, however, to each other in partial image or partial grid or field exchanged, and accordingly it is necessary to determine the waveform of a transmission pulse for auxiliary discharge into that of another transmission pulse for interlaced scanning partially raster to transmit, resulting in a very complicated driver circuit leads. It can also be if the one subject to interlaced scanning Cathode transmission pulse to be applied has a pulse width less than about 10 ps owns, d. H. smaller than the horizontal blanking interval, that sometimes happens the transmission is prevented. It is therefore the object of the invention to provide an improved To provide a flat display which is suitable for interlaced scanning is easy to manufacture and has a large display or mapping area.

To solve this problem, the invention provides two, one each Pairs of I'clirlarionc-rl, which form the main discharge space, with ciner Cathode plate are provided, whereby an interlaced scan by alternately generating a Main discharge in one pair of perforations and in the other pair of perforations is effected.

The object is achieved according to the invention in that the perforations are formed in the cathode electrodes and divided into two groups, the first of which Group contains several of at least two perforations, one below the other first slots are connected, which are at first crossing points between the auxiliary anode electrodes and the cathode electrodes are arranged, and the second group thereof is a plurality of each contains at least two perforations, one below the other via second slots are connected at second crossing points between other auxiliary anode electrodes than those crossing the first slits and the cathode electrodes are to generate the main discharges in the perforations by alternating Facilitate auxiliary discharges through the first slots and the second slots.

The invention therefore provides a flat display with an insulating substrate, which is provided with several auxiliary discharge channels, each with an auxiliary discharge anode electrode is, with a plurality of anode conductors arranged on the insulating substrate, except at certain, outwardly exposed sections, with an insulating material or D ielektrikum are covered with several cathode plates that the auxiliary discharge channels cross and interact with the exposed ali cuts of the anode conductor Have perforations, with a transparent touching the cathode plates Insulating plate and with a fluorescent material inside the respective perforations the cathode plates is applied, with a given gas in the auxiliary discharge channels and the perforations of the cathode plates is filled, the airtight are closed to the outside, wherein - the auxiliary discharge anode electrodes at least are alternately coupled paralles, and by switching the parallel alternately coupled auxiliary discharge anode electrodes in response to corresponding sub-rasters of a desired image main discharges are generated in the perforations, to interlace an image in response to the corresponding sub-rasters to represent.

The invention is based on the exemplary embodiments shown in the drawing explained in more detail. 1 shows the structure of a conventional one in perspective Flat display, Fig. 2 shows an improved conventional flat display according to a plan view Fig. 1, Fig. 3A to 3D sectional views lIlA - lIlA ', IIIB - IIIB', IIIC - lIIC ' or IIID - IIID 'in Fig. 2, Fig. 4 in view of the structure of a flat display according to of the invention, FIGS. 5A and 5B sectional views VA - VA 'and VB - VB' in FIG. 4, 6 schematically shows the mode of operation of a flat display according to FIG Invention.

The conventional flat displays shown in FIGS. 1 to 3 D have already been explained in more detail above.

As shown in Figs. 4, 5A and 5B, in which the same or similar parts as in Figs. 1 and 2 are provided with the same reference numerals, a flat panel display according to the invention includes a plurality of cathode electrodes or plates 5, the lengthwise with perforations 6-1 (above in Fig. 4) and perforations 6-2 (below in Fig. 4) are provided (consequently upper main discharge spaces 13-1 and lower main relief chambers 13-2). In particular, everyone contains Strips or each band of cathode plates .5 multiple pairs of top perforations 6-1 and several pairs of lower perforations 6-2.

A pair of upper perforations 6-1 is connected to a channel 8 via one line 14-1 formed in the cathode strip 5 is connected. In the same way is a pair of lower perforations 6-2 with a channel 8 through one in the cathode strip 5 formed line 14-2 connected. The slots or lines 14-1 and 14-2 are arranged so that the pair of perforations with crossing points of an auxiliary anode electrode 9 and the cathode plate 5 are connected. That is, that where one with a main discharge space 13-1 connected auxiliary anode electrode 9 in detail as an auxiliary anode electrode 9-1 is designated and another, a different discharge space 13-2 belonging to it Electrode 9 is referred to in detail as an auxiliary anode electrode 9-2, the one Line 14-1 the auxiliary anode electrode 9-1 and the other line 14-2 the auxiliary anode electrode rode 9-2 crosses. While the pair of upper main discharge spaces 13-1 with a one Channel 8 forming auxiliary discharge space through the channel 8 formed in cathode plate 5 Line 14-1 communicates to be supplied with electrons and metastable atoms to be able to, by an auxiliary discharge between the auxiliary discharge anode electrode 9-1 and the cathode plate 5 are produced, accordingly, the pair of lower main discharge spaces stand 13-2 with another channel 8, which forms other auxiliary discharge spaces h (Ij line 14-2 in connection, uIn with egg troneii are metastable Atoms to be supplied by an auxiliary discharge between the auxiliary discharge anode electrode 9-1 and the cathode plate 5 are produced.

With such a structure, by applying a voltage to the auxiliary discharge anode electrodes 9-1 and 9-2 alternately in response to respective ones Partial grid of the image, regardless of the fact that one to be applied to the cathode plate 5 Transmission pulse chip polarity for auxiliary discharge takes the form of one for interlaced scanning assumes specific multi-phase voltage, the pair of main discharge spaces 13-1, the is formed in the same cathode plate 5, discharged in response to a partial grid at which a voltage is applied to the auxiliary discharge anode electrodes 9-1 is, and the other pair of main discharge spaces 13-2 may in response to the following Partial raster are discharged at which a voltage is applied to the auxiliary discharge anode electrode 9-2 is created. Understandably, this enables a simple interlace scanning operation.

With reference to Fig. 6, in which the auxiliary discharge anode electrodes 9-1 and also the auxiliary discharge anode electrodes 9-2 connected in parallel with each other the operation of a flat panel display according to the invention will be explained. In the Figure are shown a transfer switch 15 for applying a voltage the auxiliary discharge anode electrodes 9-1 and 9-2 in response to corresponding sub-grids, and a voltage supply 16 for the auxiliary discharge anode electrodes, wherein alternately an output voltage to the auxiliary discharge anode electrodes 9-1 and 9-2 is applied via the transfer switch 15. Next are shown a Gradation or tint switch 17 for controlling the tint of a displayed image and an anode lead power supply 18, the period in which one Voltage of the voltage supply 18 is applied to an anode conductor 2 through which Tint switch 17 is regulated or controlled.

A connection RT to an additional cathode plate is also shown 5 R applied reset voltage 19, which is used to control the start of scanning for the auxiliary discharge is provided, as well as a three-phase clock pulse 20, 21, 22 for transmitting the auxiliary discharge, which is applied to each individual cathode strip via the connections T17 T2, T3, ... is, in particular with the first phase pulse 22. In general, the transmission pulse be a multiphase pulse with more than three phases.

Although so far the feature of a flat display according to the invention has been described with regard to interlaced scanning, it is furthermore advantageous that the production is facilitated.

In particular, there where a space between picture elements can be identical is, the cross-sectional area of the cathode plate 5 according to the invention is more than twice be as large as' with conventional flat displays. This has the consequence that the The cathode plate is free from deformation, which is why the flat display is easy to handle is.

Since furthermore, the number of cathode plates is reduced by half production can be facilitated.

So far, the invention is based on an exemplary embodiment has been described in which the anode conductor is provided for the insulating substrate are, but of course other embodiments can also be selected, z. B. the anode leads can be used for the transparent insulating substrate substantially parallel to the auxiliary discharge anode electrodes. In this case can an additional insulating part between the cathode plates and the anode conductors may be provided, wherein the additional insulating part z. B.

can be an insulating plate with perforations.

Claims (3)

Patent claims (Flat display with several anode electrodes, the several cathode electrodes cross, at crossing points between the anode electrodes and the cathode electrodes provided perforations, -and several auxiliary anode electrodes crossing the cathode electrodes, the beginning of main discharges to be generated in the perforations through auxiliary discharges generated between the plurality of cathode electrodes and auxiliary anode electrodes is facilitated to display a desired image, characterized in that the perforations (6) are formed in the cathode electrodes (5) and in two groups are divided, the first group of several of at least two perforations (6-1) which are connected to one another via first slots (14-1) which at the first crossing points between the auxiliary anode electrodes (9) and the cathode electrodes (5) are arranged, and the second group has several of at least two perforations (6-2) which are connected to one another via second slots (14-2) which at second crossing points between other auxiliary Anode electrodes (9) as those crossing the first slits (14-1) and the cathode electrodes (5) are arranged in order to generate the main discharges in the perforations (6) by alternating auxiliary discharges through the first slots (14-1) and the second Slots (14-2) to facilitate. 2. Flat display according to claim 1, characterized by one with several Insulating substrate (7) provided with channels (8), each channel (8) having an auxiliary anode electrode (9) contains several essentially parallel to the auxiliary anode electrodes (9) arranged anode conductor (2), each anode conductor (2) except for several specific Sections (12) is carried by an insulating part, several of the anode conductors (2) crossing cathode electrodes (5), each of the cathode electrodes (5) having perforations (6) connected to the specific sections (12) of the anode conductors (2), and having separate slots (14-1, 14-2) around the same anode conductor (2) arranged perforations (6) on sections where the anode conductor (2) is open to the outside, with the perforations arranged along other anode conductors (2) (6) to connect to the specific sections (12) of the anode conductor (2), one the individual perforations (6) coating the phosphor (10), and one the cathode electrodes (5) touching translucent Insulating substrate (1) to the The channels (8) and the perforations (6) are airtight so that they can be connected to a given discharge gas can be filled by auxiliary discharges in the channel (8) in the perforations (6) to generate alternating main discharges to achieve a Interlace scanning. 3. Flat display according to claim 2, characterized in that the a plurality of auxiliary anode electrodes (9) a first group of auxiliary anode electrodes (9-1), which are at least alternately coupled in parallel, and a second group of auxiliary anode electrodes (9-2), which the other opposite the alternating Couplings of the first group alternately couples in parallel, and the cathode electrodes (5) a first group of perforations (6-1) with the channels (8) in which the first group of auxiliary anode electrodes (9-1) is arranged, and a second group of perforations (6-2) with the other channels (8) in which the second group the auxiliary anode electrode (9-2) is arranged, connect to the main discharges alternately through the first group of auxiliary discharge anode electrodes (9-1) and to produce the second group of auxiliary discharge anode electrodes (9-2).