DE3911351A1 - FLAT DISPLAY DEVICE - Google Patents

Description

Technical field

The invention relates to a flat display device with a Row selection arrangement for selecting electrons only for one line each of an image to be displayed.

State of the art

Electrons, among which a spatial selection can be made on below different ways are generated. The most common elec Tronenquelle is with the help of oxide-coated cathodes wires realized. But they are also flat display units with electron generation using a plasma or with electron generation at electrode tips that have a high Are subject to tension. The cathodes can flä can be generated in rows, in sections or in rows. A areal production with the help of cathode wires is over the book "Flat Panel Display and CRTs", van Nostrand Reinhold Company, New York, 1985, specifically from the printed article "Flat Cathode Ray Tube Displays" by W. F. Goede, pp. 186 and 187. Selection of electrons from the areal electron cloud is generated by a lot layered electrode arrangement, as described in the same book of same author on pages 202-207. In each A predetermined Be is hidden at the electrode level reichs, so that ultimately not a row and column choice is made, but a point selection. From EP 02 50 821 A2 (US-Ser.No. 0 64 229) is a flat display device knows, in which electrons are generated in areas. To are only two adjacent ones of a multitude in rows  Direction of heating wires at emission potential switches. With the help of a row selection arrangement, the one Contains a large number of row electrodes is made from each one line currently covered by electrons chooses. From US 42 27 117 A is a flat display device known, which is operated so that from a variety of Cathode wires only one by one on emissions potential is laid. With a pull anode, each because emitting wire electron beams are withdrawn, the Diameter corresponds approximately to the height of a line. The elec Tron rays within a row are repeated and all distracted at the same time to cover several lines nen.

This is common to the different principles mentioned same aim to turn on a flat display give the fewest possible connections to influence the Electrons needed and the best possible electron optical Has properties, d. i.e., at electron beams by the means for selecting rows and columns and for Brightness control can be distorted as little as possible. These Efforts are ongoing. They are also the basis of the invention.

Presentation of the invention

The flat display device according to the invention stands out by a cathode / row electrode synchronizing circuit out, the cathode wires in sections and row electrodes controlled in some areas. Summarizing the line electro The area saves a large number of connections. It is particularly important that the cathode wires are so in in relation to their mutual distance and the distance to Row selection arrangement are arranged and such potential conditions are subject to that of at least each  two adjacent emitting cathode wires Electrons cover approximately an area, the height of which Height of a row electrode group corresponds. this makes possible it to le numerous row electrodes to pass potential gene, but still achieve that only by a line trode pass electrons, namely precisely through the one which is in the area that is currently on emissions potential switched cathode wires with electrons over cover.

The display device according to the invention is accordingly Based on the principle from the book mentioned above. The Area selection, however, is not exclusively in tax made electrode layers, but the already existing The cathode arrangement is included in the selection. This creates a separate selection electrode layer saves. It is important that the Katho the arrangement can be integrated into the area selection, are the above geometric and potential conditions. In order for these conditions not only for one the specified synchro works nisier circuit so that it repeats repeatedly in succession the row electrodes 1-m from top to bottom on passage potential and the other row electrodes to blocking potential, and then, if with one to pass switched row electrode has reached a height that in corresponds approximately to the height of an emitting cathode wire, switches the cathode wire to non-emission that within the range of the height of the row electrode group still emitted as the top one, and then those cathodes wire switches to emission, which is directly below that lowest emitting cathode wire.  

It is particularly advantageous to use Seg for brightness control to insert ment electrodes that are close behind the cathode wire at right angles to these. The brightness control then does not have to take place on selected electron beams, what affects their focus, but it becomes the Intensity of the generated electron cloud controlled what it dispensable, on selected electron beams to help influence control.

In a practical embodiment with a screen height of approximately 17 cm, 276 row electrodes were used. These were divided into 19 groups, so that only 19 were required instead of 276 row electrode connections. In order to be able to contact every 19th row electrode in a simple manner, it is advantageous to use a contacting component around which a predetermined number of conductor tracks are wound with a mutual spacing, the distance between two adjacent row electrodes or an integer multiple thereof Distance corresponds, and with a slope which corresponds to the mutual distance of the predetermined number m of row electrodes in a group. It is particularly advantageous to use two such contacting components, one electrode arrangement along each of the two high sides of a row electrode. From a respective one of the two contact components, only every second row electrode is contacted on one side, that is to say on one side all even-numbered and on the other side all odd-numbered row electrodes.

Brief description of the figures

Fig. 1 is a schematic perspective view of the arrangement of electrodes in a flat display device;

Fig. 2a circuit diagram illustrating how cathode wires and row electrodes are controlled by a cathode / row electrode synchronizing circuit;

FIG. 2b shows five time-shifted diagrams to illustrate how electrons are passed through row electrodes when driving with the aid of the circuit according to FIG. 2a;

Fig. 3 is partial plan view of a row electrode array;

Fig. 4 is a schematic perspective view of a contact processing component for contacting each 19th row electrode of the arrangement according to Fig. 3;

Fig. 5 is schematic plan view of a row electrode arrangement with a Kontaktierungsbauteil according to Fig 4 on one side of the arrangement.

Fig. 6 representation of FIG. 5, but each with a contacting component Kon along both high sides of a row electrode arrangement.

Ways of Carrying Out the Invention

Fig. 1 shows the functional parts of an embodiment of a flat display device without brackets and without a tub enclosing the functional parts together with a front plate 10. The flat display device has a base plate 11 from the rear to the front with segment electrodes S applied to it in the column direction, cathode wires in the row direction, pull anode electrodes in the column direction, row electrodes in the row direction, column electrodes in the column direction and the front pane 10 already mentioned with phosphor strips 12 applied thereon and an aluminization (not shown) over the phosphor strip that serves as an anode. In Fig. 1, only a few segment electrodes are shown ( S 1 , S 2 and S 3 ), but in a practical example for a flat display device with a screen having a height of approximately 17 cm and a width of approximately 21 cm, there are 198 Segment electrodes that are as close together as possible on the insulating base plate 11 . The cathode wires mentioned run at a distance of about 0.5 mm in front of these segment electrodes, 30 pieces in the practical exemplary embodiment, but only 5 pieces K 1 - K 5 in FIG. 1. The train anode level is about 2 mm before the level of the cathode. There are 199 pull anode electrodes, five of which are shown in FIG. 1, which are denoted by P 0/1 , P 1/2 , P 2/3 , P 3/4 and P 4/5 . The row electrode level is only about 150 µm in front of the Zugano level. It has 276 cell electrodes, six of which are shown in Fig. 1 with the designations L 1- L 6 . The column electrode level lies another 150 µm in front of the row electrode level. There are 199 column electrodes, five of which are shown in FIG. 1 and are designated C 0/1 , C 1/2 , C 2/3 , C 3/4 , and C 4/5 . The front pane 10 is located approximately 8 mm in front of the column electrodes. It carries 388 triples of fluorescent strips R , G and B , making a total of 1164 strips.

In order for a cathode wire to emit electrons, corresponding potentials must be applied to it, the segment electrodes and the train anode electrodes. Reference potential for all these potentials is the potential of an emitting cathode wire. The emission potential is therefore set to 0 V. When it is sufficiently hot, a cathode wire emits at all those points at which the potentials of the segment electrodes and the pull electrodes are sufficiently higher than the emission potential. These conditions are met in the potentials shown in FIG. 1 for the cathode wire K 4 in front of the segment electrodes S 1 and S 3 . This is because the train anode electrodes are at +30 V and the segment electrodes mentioned are at +20 and +10 V, respectively. The segment electrode S 2 , however, is at -10 V, which is why the cathode wire K 4 does not emit any electrodes in front of it. The other cathode wires do not emit electrodes because they are all at +20 V. Therefore, the segment electrode potentials are not sufficiently high, nor is the pull anode potential sufficiently high that electrodes can be emitted. The non-emitting cathode wires K 1- K 3 and K 5 are heated. On the other hand, the heater is switched off for the emitting Ka wire K 4 , so that no potential drop occurs along its length due to the heating voltage.

Electrons that are emitted from the cathode wire K 4 in front of the segment electrode de S 1 pass between the train anode electrodes P 0/1 and P 1/2 , while electrodes in place in front of the segment electrode S 3 between the train anode electrodes P 2/3 and P 3/4 step through. The electron beam that passes through is spread out in the column direction, that is, higher than the height of a row. With the help of the row electrodes, electron beams are separated out from the spread bundles for the points of a single row. In the example shown in FIG. 1, the third next row electrodes are connected to each other, that is, the electrodes L 1 and L 4 with each other and the electrodes L 2 and L 5 with each other, while for the electrode L 3 there is a separate connection since it is connected to a third next row of electrodes is missing. In the practical embodiment, the 19 connections are available for the above-mentioned 276 line electrodes, with 15 electrodes and 10 connections and 14 electrodes being contacted via 10 connections. In the example shown, the row electrodes L 1 and L 4 are at +20 V, while the other row electrodes are at -20 V. Because of these potential ratios, electrons can only pass through row electrode holes 13 in the row electrodes L 1 and L 4 . However, electrons are only present at the row electrodes L 3 , L 4 and L 5 . Therefore, only electrons pass through the row electrode L 4 . A front electron beam 14. V and a rear electron beam 14. H are thereby formed. The front electron beam 14. v comes from the location of the cathode wire K 4 in front of the segment electrode S 1 . The rear electron beam 14. h , however, comes from the location of the cathode wire K 4 in front of the segment electrode S 3 . Since the segment electrode S 3 is at a higher potential than the segment electrode S 1 , the rear electron beam 14 h is stronger than the front 14 v , which is why the dashed line for the rear electron beam is drawn more strongly than that for the front beam.

The front electron beam 14. v passes between the column electrodes C 0/1 and C 1/2 , while the rear 14th h passes between the column electrodes C 2/3 and C 3/4 . Each column after the next is connected to the same potential. In the case shown, the column electrodes C 0/1 and C 2/3 receive a potential of +60 V, while the column electrodes C 1/2 and C 3/4 receive a potential of +65 V. As a result, the two electron beams mentioned are deflected somewhat forward.

A total of 6 fluorescent strips can be scanned by each of the electron beams. For example, an electron beam that comes from a cathode wire in front of the foremost segment S 1 can hit three strips on the left and right of its undeflected position. If it is deflected furthest to the left, forwards in the picture, it hits a fluorescent strip R 1.1 . If he is deflected a little less to the left, he hits a fluorescent strip G 1.1 , and with even less deflection to the left a fluorescent strip B 1.1 . With increasing deflection to the right, fluorescent strips R 1.2 , G 1.2 and B 1.2 can be reached. The same applies to the other electron beams. The fluorescent strips on the far right (rear) in FIG. 1 have the indexes R 3.2 , G 3.2 and B 3.2 . They are reached by electron beams, which originate from cathode wires in front of the rearmost segment S 3 and which are then deflected to the right by potentials at the column electrodes C 2/3 and C 3/4 .

For the front electron beam 14. v according to the example explained with reference to FIG. 1, it is assumed that it hits the fluorescent strip G 1.1 , while the rear electron beam 14. h hits the fluorescent strip G 3.1 .

To generate an image, the cathode wire K 1 is first set to emission potential and the segment electrodes S 1 and S 3 receive potentials which determine the brightness which is to be achieved on the phosphor strips R 1.1 and R 3.1 . The row electrode L 1 is driven so that it lets electrons pass. Then the row electrode L 4 is at pass potential, which, however, is not a problem since no electrons arrive there. The column electrodes are driven in such a way that the phosphor strips mentioned are hit. At closing, the signals for the green field are placed on the segments S 1 and S 3 and the column electrodes are supplied with potentials which ensure that the electrons are deflected somewhat less than before, so that the green phosphor strips are hit. These processes are repeated until all six fluorescent strips are scanned, each of which is assigned to a segment. At closing, the segments S 1 and S 3 are set to the blocking potential and the voltages that are required to achieve the desired brightness at the middle six phosphor strips in sequence are successively placed on the central segment. The fluorescent strips are scanned using the column electrodes. If all phosphor strips in a row are scanned in this way, the cathode wire K 1 is set to non-emission potential and the cathode wire K 2 is set to emission potential. The processes described are repeated one line at a time.

The principle of row selection is now illustrated further with reference to FIG. 2.

In Fig. 2a 10 row electrodes L 1- L 10 are shown, to which five cathode wires K 1- K 5 are assigned. All cathode wires K 1- K 5 are individually connected to a cathode / row electrode synchronizing circuit 15 . The row electrodes L 1- L 10 , on the other hand, are connected in groups, arranged in g = 4 groups. The group with the consecutive number G = 1 as well as the group with the consecutive number G = 2 comprises n = 3 lines. The other two groups with the consecutive numbers 3 and 4 , on the other hand, each contain m ′ = 2 lines. The geometrical dimensions and the potentials are chosen so that electrons from the cathode wire K 1 cannot pass through the third row electrode L 3 . Accordingly, electrons from the cathode wire K 2 cannot pass through the first row electrode L 1 and the fifth row electrode L 5 . The electrons from a single cathode wire each cover approximately a height that corresponds to twice the distance between two row electrodes. Since row electrodes, which belong to a common group, are each four distances apart, two emitting cathode wires are required to cover this area.

The time sequence in the operation of the arrangement according to FIG. 2a is shown in FIG . At an initial point in time, the cathodes K 1 and K 2 are at emission potential. The remaining cathode wires are set to non-emission potential and they are heated using a heating voltage. All rows electrodes in the group with the group number G = 1 are supplied with pass potential, that is, the row electrodes L 1 , L 5 and L 9 . Since the emission of the second cathode wire K 2 does not reach the scanning electrode L 5, only pass through the row electrode 1 L electrons therethrough. It is pointed out that some electrons will also pass through the row electrode L 5 , but that the geometrical and potential conditions ensure that the power transmitted by these electrons to the luminescent screen is kept so low that the latter Electron-excited line is not visible.

At a subsequent point in time, all row electrodes with group number G = 2 are supplied with pass potential, that is to say row electrodes L 2 , L 6 and L 10 . Nothing changes in the control ratios for the cathode wires. Electrons then pass through the row electrode L 2 and are supplied jointly by the cathode wires K 1 and K 2 .

At a third point in time, all line electrodes with group number G = 3 pass potential. These are the row electrodes L 3 and L 7 . Electrons from the previously emitting cathode wire K 1 can no longer reach the row electrode L 3 , which is why the cathode wire K 1 is set to non-emission potential. However, it is not yet applied to heating voltage. This procedure is justified in conditions that occur in the dynamic case when electrons from a single cathode wire cover many row electrodes, when switching quickly and when temporary potentials at the row electrodes and cathode wires could ensure that due to a superimposed one Heating voltage still sets an undesirable emission. When the cathode wire K 1 is switched off, the cathode wire K 3 is set to emission potential. However, no electrons pass through it through one of the row electrodes. Rather, only electrons from the cathode wire K 2 pass through the row electrode L 3 .

At a fourth point in time, forward potential is finally applied to all row electrodes with group number G = 4. These are the row electrodes L 4 and L 8 . Electrons from the cathode wires K 2 and K 3 pass through the row electrodes L 4 . The row electrode L 8 receives no electrons.

In a fifth point in time, the state according to the first point in time is reached again with respect to the potential ratios at the row electrodes. Instead of the cathode wires K 1 and K 2 , the cathode wires K 3 and K 4 are now at emission potential. As a result, electrons from the cathode wire K 3 pass through the row electrode L 5 . The cathode wire K 2 is again at non-emission potential, but is not yet heated.

In the manner described, the process is continued until it is ensured that electrons pass through the bottom rows of electrode L 10 . Then the processes described are repeated.

How many cathodes are operated within an area, the height of which corresponds to the distance between two row electrodes belonging to the same group, depends on the respective overall circumstances, in particular the overall dimensions of a display device. It also depends on the overall operating conditions whether, whenever an upper cathode wire is connected to non-emission potential, a lower cathode wire is immediately supplied with emission potential, or whether a few line clocks are waited for. 2b as seen from FIG. Recognized that in the third cycle, the cathode K may be turned off 1, the cathode K 3 but would not be switched on. It only has to be switched on in the fourth bar. So it would easily be possible to delay one clock. If, as in practical embodiments, many rows of electrodes are covered by the electrons from a single cathode wire, it is also possible to wait for a time delay of several clocks between switching off an upper cathode wire and switching on a lower cathode wire. Switching off a Kathodendrah tes and switching on another is not necessarily at times that correspond exactly to the point in time at which a row electrode is switched on passage, which is in the amount of an emitting cathode wire, but the on and off times are only in essentially near such a time.

The principle described above can also be used who, if not only segment electrodes, cathode wires and pull anode electrodes are used to generate electron clouds, but also if additional electrode arrangements are used, possibly even without segment electrodes, as in EP 02 26 817 A2 (US Ser. No.). The arrangement specified there requires fewer cathode wires than that explained with reference to FIG. 1, since the electron cloud generated by a cathode wire can be shifted in the line direction by additional electrodes. It has been shown in practice that in a specific embodiment of the dimension mentioned above, the electrons can cover up to 30 rows by a single cathode wire. With such a cathode arrangement it is accordingly also possible to use row electrodes interconnected in groups. This is because electrons are no longer made available over the entire area of the display device, but only within a narrowly limited area. Very few row electrode groups are then sufficient. The distance between cell electrodes within the same group must always be somewhat larger than the area covered by cathode rays.

In Fig. 3, a row electrode arrangement is shown, as it can be used both in an electron generation according to Fig. 1 and in such according to the aforementioned EP 02 26 817 A2. It has 276 row electrodes L with 194 holes 13 each. All 19th electrodes are connected to each other, whereby 10 groups with 15 electrodes connected to each other and 9 groups with 14 electrodes connected to each other are formed.

The contacting of the row electrode arrangement according to FIG. 3 takes place with the aid of a contacting component 16 , as is shown schematically in FIG. 4. It has an elongated parallelepiped-shaped support 17 , around which 19 tracks 18 are wound helically, of which only two are shown for the sake of clarity. The conductors can z. B. be evaporated. However, there are more expedient manufacturing processes, which are described in a parallel application. The conductor tracks 18 have a mutual distance, which corresponds to the mutual distance of two rows of electrodes. The slope corresponds to the distance of 19 row electrodes. This contacting component 16 is placed on the row electrode arrangement according to FIG. 3 such that the row electrodes with the numbers 1 , 20 , 39 , 58 , etc. are contacted by the first conductor track 18.1 .

If only a single contacting component 16 is used, it is placed on or attached to a high side of the row arrangement according to FIG. 3, as shown schematically in FIG. 5. At the schematic diagram of FIG. 5, each group contains four row electrodes. Of the associated four conductor tracks in the contacting component 16 in FIG. 5, each first is drawn more intensely. In the embodiment according to FIG. 5, the four conductor tracks are contacted via four connections 19.1-19.4 that are as far as possible from one another. The connections can also be directly next to each other if this is cheaper for making contact in the overall component.

In the arrangement according to FIG. 6, two contacting parts 16.1 and 16.2 are provided for odd or even numbered electrodes. This configuration has the advantage that each contacting component only has to contain half of the conductor tracks, as are required for the contacting component 16 according to FIG. 5. As a result, the conductor tracks can be kept relatively wide at least in those areas in which they do not contact the row electrodes, which reduces the line resistance. This ensures that the same potential is supplied to all row electrodes with the same time behavior.

Claims (7)

1. Flat display device, characterized by

• a) a row selection arrangement a1) which contains a plurality of row electrodes ( L 1- L 5 ) which are arranged in g groups, all row electrodes having the same number (from 1- m ) in the different groups G (from 1- g ) are connected to each other,
• b) a cathode arrangement b1) with heated cathode wires ( K 1- K 5 ) which run in the direction of the row electrodes and whose emission is controllable, b2) which cathode wires are arranged in relation to their mutual spacing and the distance to the row selection arrangement and are subject to such potential ratios that they cover electrons emitted by at least two adjacent emitting cathode wires in approximately one area, the height of which corresponds to the height of a row electrode group,
• c) and a control arrangement for controlling the operation of the row selection arrangement and the cathode arrangement, c1) with a cathode / row electrode synchronizing circuit ( 15 ) which repeatedly sets the row electrodes of the groups from top to bottom to pass potential in succession and thereby the respective other row electrodes to blocking potential, and which whenever a electrode switched to pass has reached a height which corresponds approximately to the height of an emitting cathode wire, switches the cathode wire to non-emission which group within the range of the height of the row electrodes still emitted as the top, and which then switches that cathode wire to emission, which is directly below the lowest emitting cathode wire until then.

2. Flat display device according to claim 1, characterized in that the synchronizing circuit ( 15 ) interrupts the heating of each cathode wire ( K 1- K 5 ) at least in the time period within which it sets it to emission potential. 3. Flat display device according to claim 2, characterized in that the synchronizing circuit ( 159 ) at the earliest then applies heating voltage to a cathode wire ( K 1 - K 5 ) when it switches the following cathode wire to non-emission. 4. Flat display device according to claim 1, characterized marked by segment electrodes ( S 1- S 3 ) which run directly behind the cathode wires ( K 1- K 5 ) at right angles to these. 5. Flat display device, characterized by a ') with a line selection arrangement
a'1) a variety of row electrodes ( L ) and
a'2) at least one elongated contacting component ( 16 ; 16.1 , 16.2 ), the length of which corresponds to the height of the row selection arrangement and around which a predetermined number of conductor tracks ( 18 ) are wound at a mutual distance which is the distance between two adjacent row electrodes or corresponds to an integer multiple of this distance, and with a slope that speaks to the mutual distance of the predetermined number of row electrodes in a group,
a'3) wherein the row electrodes are connected to the conductor tracks of the at least one contacting component in such a way that g groups of row electrodes are formed, within which each is connected to the same conductor track with the same number. 6. Flat display device according to claim 5, characterized by a single contacting component ( 16 ) with as many conductor tracks as groups are present, the mutual spacing of which corresponds to the mutual spacing between adjacent row electrodes ( L ), which contacting component is arranged along a high side of the row selection arrangement is. 7. Flat display device according to claim 5, characterized by two contacting components ( 16.1 , 16.2 ), each with a number of conductor tracks, which corresponds to half the number of groups, and their respective mutual distance twice the mutual Ab stood adjacent row electrodes ( L ) corresponds, the one contacting component being arranged along a high side and the other contacting component being arranged along the other high side and contacting the conductor tracks of the one contacting component ( 16.2 ) evenly numbered row electrodes and contacting the conductor tracks of the other contacting member ( 16.1 ) odd numbered row electrodes .