EP0109010A2 - Flat imaging device - Google Patents

Abstract

In a flat screen, in which electrons are generated in a rear space (6), are guided through selectively opened holes of an electron matrix into a front space (5) and are directed there to a phosphor point, the deflection system is designed as follows: the rows of rows parallel to the columns of the electrode matrix are each surrounded by two elongate deflection electrodes (vertical deflection electrodes 16, 29 or horizontal deflection electrodes 17, 28), only a single electrode being located between adjacent rows of holes. A three-color screen is preferably designed as follows: the line conductors (11) are keyed one after the other and in each case remain activated for two image line periods; the column conductors (12) receive the associated information signals during each picture line period, one by one in color; the vertical deflection potentials are switched in time with the line conductor advancement, but shifted by one picture line period; the horizontal deflection electrodes (17, 28) are driven at three times the frame rate. The proposed deflection system is relatively easy to manufacture, is rollover-proof and does not require any special contacting and switching effort. Main area of application: Highly informative displays, especially color television screens.

Description

The invention relates to a flat tube according to the preamble of claim 1. Such a screen is described in DE-OS 27 42 555.

The previously known display works according to the following principle: electrons, which are generated in a large area in a rear room, pass through selectively opened holes in an electrode matrix into a front room, in which they are accelerated and finally hit a front fluorescent screen. This concept leads to a relatively flat design and makes it possible, at least if the electrons are obtained from a wedge-shaped gas discharge and the post-acceleration space is kept plasma-free using the Paschen law (DE-PS 24 12 869), also an optically perfect representation of rapidly moving processes . However, with increasing pixel density, it becomes increasingly difficult to precisely design the electrode matrix with its filigree line pattern and its fine hole pattern on the entire display surface.

These manufacturing difficulties are alleviated if the individual electron beams are scanned by a number of pixels by means of a targeted deflection. In the publication cited at the beginning, it is proposed to insert two further insulating plates into the post-acceleration space, with openings that are respectively in front of the row conductors or column conductors of the electrode matrix and on their walls parallel to the rows or columns are provided with a deflection electrode; the electrodes of each plate are interconnected in the manner of interdigitated combs. The tube can be used to display colored television pictures and is then controlled as follows: the matrix lines are keyed one after the other, and during a line keying time T all columns receive the associated data signals simultaneously, namely the three color separations of the complete line information. The column-parallel deflection electrodes are switched in time with the color change, such that the electrons are deflected to the left once during the period T, once fly straight ahead and once are deflected to the right. The line-parallel deflection electrodes, which deflect the electrons upwards and downwards, are switched over when a field is built up; they ensure interlacing of fields.

In the case of such a two-dimensional beam deflection, the number of matrix openings can be drastically reduced and the control and contacting effort is significantly lower. On the whole, however, the manufacturing facilities are only relatively modest, since the deflection electrode systems have to be prepared very carefully, especially since there can easily be flashovers between the closely adjacent electrode pairs.

The invention is therefore based on the object of developing a display device of the type mentioned which can be manufactured more conveniently and basically manages with the same number of connections and the same switching means. This object is achieved according to the invention by a picture tube having the features of patent claim 1.

The proposed solution is based on the consideration that the deflection electrode pairs respectively assigned to the matrix conductors do not have to be electrically separated from one another at all; one also achieves the goal if adjacent deflection capacitors share an electrode. If such a coupling is permitted, the number of electrodes is reduced to half and there are no longer any short circuits to fear because of the relatively large electrode spacings; in addition, the entire deflecting part can be implemented in the simplest form, for example as a cross grid made of tensioned wires. The number of external contacts need not increase, because here too the horizontal and the vertical deflecting electrodes can be combined interdigitally. In principle, the addressing technology can also remain the same: with vertical deflection, you will at most switch to other switching cycles and phases, and the horizontal deflection can be controlled in a conventional manner. It should be noted, however, that neighboring electron beams of a row are always deflected in opposite directions; if necessary, the color dots on the fluorescent screen should be rearranged, for example from the usual color sequence red-green-blue to the red-green-blue-blue-green-red scheme. If one wanted to stick to the usual color distribution, the circuit would have to be designed in such a way that adjacent column conductors receive their row information signals with reversed color order during each row scanning time; as is evident from the older, as yet unpublished patent application P 32 35 894.6, this is readily possible.

Advantageous refinements and developments of the invention are the subject of further claims.

• Figur 1: ein erstes Ausführungsbeispiel in einer teilweise weggebrochenen Perspektivansicht;
• Figur 2: von einem weiteren Ausführungsbeispiel den vorderen Teil, von oben gesehen und teilweise weggeschnitten;
• Figur 3: die Figur 2 im Schnitt III-III;
• Figur 4: die - teilweise weggebrochene - Ablenkeinheit eines dritten Ausführungsbeispiels, in einer Vorderansicht;
• Figur 5: die Figur 4 im Schnitt V-V;
• Figur 6: die bei allen Ausführungsbeispielen identische Steuerplatte, teilweise weggebrochen und von vorn gesehen, mit einem Farbtripel aus der vorgelagerten Kathodolumineszenzschicht.

The invention will now be explained in more detail using exemplary embodiments with reference to the accompanying drawing. Corresponding parts in the figures are provided with the same reference symbols. Show it:

• Figure 1: a first embodiment in a partially broken perspective view;
• Figure 2: from another embodiment, the front part, seen from above and partially cut away;
• Figure 3: Figure 2 in section III-III;
• Figure 4: the - partially broken - deflection unit of a third embodiment, in a front view;
• Figure 5: Figure 4 in section VV;
• FIG. 6: the control plate which is identical in all of the exemplary embodiments, partially broken away and seen from the front, with a triple color from the preceding cathodoluminescent layer.

For the sake of clarity, the figures are sometimes kept very schematic; Individual parts such as electrode leads, plated-through holes or mounting elements which do not contribute to an understanding of the invention are omitted.

The flat screen of Figure 1 is used to display black and white television pictures. It contains in particular a gas-filled envelope 1 with a back plate 2, a front plate 3 and a control plate 4. All three parts extend in mutually parallel planes, the control plate dividing the interior of the envelope into two chambers, a front acceleration chamber 5 and a rear gas discharge chamber 6.

The back plate 2 is provided on its front side with a family of parallel, relatively large-area cathode strips 7. The front plate 3 has a regular grid of phosphor strips 8, 9 on its rear side and a post-acceleration anode 10 above it.

The control plate 4 has the following structure: a backing made of insulating material is provided on its rear and front side with a group of strip-shaped, parallel conductors (row conductor 11 or column conductor 12). The row conductors run parallel to the cathode strips 7 and the column conductors extend perpendicularly thereto. The plate and the conductor are broken through at the points of intersection of the electrode matrix, so that electron passage openings 13 result. Each row of openings parallel to the row conductor is assigned a pair of phosphor strips 8, 9, which are offset somewhat upwards or downwards relative to the openings.

The control plate 4 is preceded by a deflection unit 14, which in the present case consists essentially of wires 16. The wires are located in a plane parallel to the control plate 4 and are arranged such that, viewed from a direction perpendicular to the control plate plane, they each run between two adjacent rows of openings parallel to the line conductor. The even and odd wires are each one. common (not shown) voltage source connected.

When the tube is in operation, the following voltages are present on the individual electrodes: on the selected and non-selected cathode strips - 200 V or 0 V; 0 V or -50 V on the sensed and non-sensed row conductors; on the column conductors between -80 V and -30 V; on the even-numbered and odd-numbered deflection electrodes either +50 V or -50 V or -50 V or +50 V; and at the post-acceleration anode + 4KV. The row conductors are keyed one after the other, i.e., successively raised to the voltage 0 V. The cathode voltages are synchronized with the line scanning voltage in such a way that a plasma burns between the selected line conductor and the opposite cathode strip during the line advancement. The column conductors receive the information signals of two picture lines in succession during the time in which a specific row conductor is driven; each line conductor sampling time thus comprises two picture line periods. The deflection wires are switched at the switching frequency for the row conductors, in such a way that the wire connection leads one picture line period. In this way, the electron beams of each opening row are first directed onto one and then onto the other phosphor stripe of the associated pair of stripes, so that an image with double image line density is completely built up after the completion of a complete line conductor scanning cycle.

If one also wants to deflect the electron beams in the direction of the row conductor extension, the deflection unit must have a second grid electrode which is to be oriented relative to the column conductors in exactly the same way as the first grid electrode can be designed with respect to the row conductors and, moreover, can be constructed in exactly the same way.

A specific exemplary embodiment of this is shown in FIGS. 2 and 3: in front of the wires 16, further wires 17 are positioned - in a plane also parallel to the control plate - each of which runs between adjacent column conductors 12. Both electrode planes are fixed in the insulated position at the crossing points of the wires by glass solder columns 18. The glass solder columns start from the control plate 4 and thus hold the entire deflection system in an adjusted position. This electrode system is part of a display device which displays colorful images using three primary colors. The wires 17 take over the color deflection, that is to say the electron beams are successively guided to different color sections 19, 20 and 21 of a phosphor strip 8 and 9 during each image line period. For illustration purposes, paths 22, 23, 24 are shown in the figures, which can take electron beams in a certain switching state of the deflection unit.

The deflection unit could also be implemented using thin-film technology. A corresponding example is shown in FIGS. 4 and 5, in which a deflection disk 26 has openings 27 that are regularly arranged and are aligned with the openings 13 of the control disk 4, and carries strip-shaped electrodes 28, 29 on both sides. The rear electrodes 28, which provide the color scanning, each run between two rows of openings parallel to the column conductor, and the electrodes 29 on the front — they deflect the electron beams vertically — are placed between the rows of openings parallel to the row conductor. The electrodes 28 still engage with projections 31 through the openings 27 in order to extend the deflection distance. The deflection disk 26 lies on the control disk 4 in such a way that no undesired contacts are made.

The control and deflection parts should be dimensioned such that the electron beams excite the individual phosphor stripe sections over as large an area as possible in order to optimize the luminous efficacy and lifetime of the phosphor. In the normal case, the electro-optical conditions in the post-acceleration space are such that the sections 19, 20, 21 are luminescent over the entire surface. if the control plate openings 13 - usually upright rectangles - are higher and of similar width. For this purpose, FIG. 6 shows, in a representation true to scale, an example of dimensions which does not cause any particular difficulties during manufacture. The row conductors 11 and the column conductors 12 are 0.74 mm and 0.32 mm wide, respectively, and are 0.11 mm and 0.16 mm apart. The openings have an area of 0.54 x 0.20 mm ² , and the individual phosphor stripe sections 19, 20 and 21 of a color triple, which together form a square, are 0.48 mm high and 0.16 mm wide.

If the display is disturbed by a column crosstalk effect, it is advisable to separate the interdigitally interconnected vertical deflection electrodes into individual groups and to control them as follows: the group that includes the deflection capacitor in front of the row conductor currently being sensed receives the deflection voltage, while all other groups are at blocking potentials . If the cathode is subdivided, the vertical deflection electrodes opposite each of the cathode strips should be combined. Further details can be found in the earlier patent application P 3 207 685.1.

The invention is not limited to the exemplary embodiments shown. If one considers that in the present context it is essentially only a question of the vertical and, if necessary, deflection To realize even in the horizontal direction with one electrode each between adjacent row or column conductors, it becomes clear that a number of variants are still possible in terms of construction and control. For example, the information could be written field by field, in such a way that the individual line conductors remain activated for only one image line period and the line-parallel deflection electrodes are switched over in clock and phase synchronization. Apart from this, it is also conceivable in individual cases to select two adjacent line conductors at the same time, to move them line by line in the rhythm of the picture line change and to switch the vertical deflection electrodes in a clock-synchronized and phase-synchronized manner so that the electron beams of the two sensed line conductors are deflected towards each other. Two adjacent phosphor strips are excited in the same way; these double strips can therefore also be drawn together into a single strip, each running between the row conductors. Such addressing technology is available. especially worth considering if the picture elements should shine over a large area and the requirements for image resolution are not too great.

Claims (12)

1. Containing flat image display device 1a) a vacuum-tight envelope with b) an electrode matrix consisting of row conductors and column conductors upstream of the row conductors, perforated at their crossing points and dividing the inside of the casing into a rear and a front chamber, c) a flat electron source in the rear chamber, d) elongated vertical deflection electrodes in the front chamber, which are located in a plane parallel to the matrix plane and each run between rows of holes parallel to the row conductor, and with e) a layer (phosphor layer) luminescent upon electron excitation on the front shell wall; 2a) a control circuit for the line-by-line construction of an image b) scanning the line conductors one after the other, each line conductor remaining activated for at least one picture line period, c) provides the column conductors with the associated image line information signals during each image line period in such a way that the electrons supplied by the electron source can selectively pass through holes in the electrode matrix, and d) the vertical deflection electrodes at least in time with the image frequency to different potentials, such that the electrons entering the front chamber are deflected either upwards or downwards, characterized in that 1f) there is only a single one between two adjacent rows of holes parallel to the line conductor of the electrode matrix 35 vertical deflection electrode (16). 2. Device according to claim 1, characterized in that each line conductor (11) remains keyed for two image line periods and that the potentials on the vertical deflection electrodes (16) are switched in time with the line conductor advancement, but shifted by one image line period. 3. Apparatus according to claim 2, in which the phosphor layer is divided into strips parallel to the row conductors, two of which are each assigned to a row conductor, characterized in that the electrode matrix has narrow holes (13) which extend parallel to the column conductors and which are dimensioned at least as large in their direction of extension are like the phosphor strips (8, 9). 4. The device according to claim 1, characterized in that each line conductor (11) remains keyed for two image line periods, the line conductor sampling times of successive line conductors (11) each overlapping for one image line period, and in that the potentials on the vertical deflection electrodes (16) are clocked and can be switched in phase with the image line change. 5. The device according to claim 4, - characterized in that the phosphor layer is divided into strips parallel to the row conductors, one of which runs between two adjacent row conductors (11). 6. Device according to one of claims 1 to 5, with elongated horizontal electrodes in the front chamber, which are located in a plane parallel to the matrix plane, each between the column-parallel hole rows of the electrode matrix and are switched at least in time with the image line change, characterized in that there is only a single horizontal deflection electrode (27) between two adjacent rows of holes parallel to the column conductors. 7. The device according to claim 6, for displaying colorful images on the basis of three primary colors, in which the phosphor layer in strips parallel to the line conductors and the strips themselves are periodically divided into sections of different primary colors and the horizontal deflection electrodes are switched at three times the image line frequency, characterized in that the Holes (13) of the electrode matrix have a larger area than the phosphor strip sections (19, 20, 21). 8. Device according to one of claims 1 to 7, characterized in that the deflection electrodes (16, 27) by glass solder columns (18) on the support of the electrode matrix are fixed wires (16, 27). 9. Device according to one of claims 1 to 7, characterized in that in the front chamber (5) a parallel to the electrode matrix baffle plate (26) is arranged, which is provided with the matrix holes (13) aligned openings (18) and on their rear and front sides each carry strip-shaped horizontal or vertical deflection electrodes (28, 29), the horizontal deflection electrodes (28) each reaching forward with lugs (31) through the openings (18). 10. The device according to one of claims 1 to 9, characterized in that the vertical deflection electrodes (16, 29) form separate groups, within which they are interconnected interdigitally, that the groups with electrodes which are assigned to the respective sensed row conductor (11), Receives deflection potentials and that all other groups are connected to a reverse voltage. 11. The device according to claim 10, with a cathode formed from mutually parallel strips in the rear chamber, characterized in that the electrode groups each comprise those vertical deflection electrodes (16, 29) which are opposite the cathode strips (7).

Images