DE2529697B2 - COLOR IMAGE DISPLAY CATHODE BEAM TUBE - Google Patents

Description

The invention relates to a color cathode ray tube display with means for generating several electron beams, with a screen on which a multitude of in different colors Luminous phosphor areas is applied and with color selection electrodes, which a Viebqhl of Form openings for assigning each electron beam to phosphor areas of a specific color, an electron lens being formed in each opening.

Such a cathode ray tube of the refocusing type is known from US Pat. No. 3,398,309. the Refocusing is used to increase the brightness of the displayed image by enlarging the To increase the permeability of the color selection electrodes. With tubes without refocusing, a sehi large part, e.g. B. 80 to 85%, of the electrons from dei so-called shadow mask intercepted. By using refocusing, the openings in the color selection electrodes are enlarged because as a result of the focusing in the openings Electron spots on the screen are considerably smaller than the openings, so that a sufficient Landuiigstoleranz exists

The electron lens, which is in the openings of the The shadow mask of the known tube is generated is a single lens in which a relatively large voltage difference between the electrodes producing the lens

Another refocusing tube is described in US Pat. No. 2,728,024. In this tube the electron beams pass one after the other two grids consisting of parallel conductors. The too different Lattice-related conductors are perpendicular to each other and are provided with voltages that the Electron beams are influenced one after the other by two electron-optical cylinder lenses that oppose each other are rotated by 90 °, and that the overall effect of the two lenses the electron beams in one focused in a certain direction and defocused in a direction perpendicular to this direction.

A disadvantage of this known tube is also that a relatively large voltage difference is required for focusing. In addition, both form The grid is not a mechanical unit, so that the oscillation of the grid wires creates great problems. Furthermore, muC with this well-known tube, the screen can be flat.

From US-PS 36 63 854 fernci is a color picture tube known with lighting up phosphor areas in the form of parallel stripes. The electron beams are not refocused in this tube.

It is the object of the invention to provide a color picture tube of the refocusing type in which with a relatively small voltage difference a strong refocusing is achieved.

According to the invention, a quadrupole lens is formed in each opening of the color selection electrodes, unc all quadrupole lenses are oriented in the same way.

Quadruple lenses are because the electric field is perpendicular stands on the electron orbit, relatively strong, which is why mar gets by with much lower voltages The fact that a quadrupole lens will focus in a certain direction and in one to that direction Defocused in the vertical direction is not a disadvantage if all four-pole devices have the same orientation The illuminated areas of the screen are preferably in the form of almost parallel strips whose longitudinal direction is parallel to the defocusing direction of quadrupole lenses.

In a favorable embodiment of a tube according to the invention, the color selection electrodes formed by a grid consisting of two intersecting and possibly intertwined sentences consists of parallel conductors, which are insulated from each other at the crossing point, the conductors each Sentence are connected to each other.

In a further advantageous embodiment of the tube according to the invention, the color selection elements Trode formed by a metal plate with said openings and with conductive strips is provided between the rows of openings and wherein the strips are connected to each other and against the plate are insulated.

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Voltages from an external voltage source can be applied to the electrodes produced by the quadrupole lenses. It is also possible, leading from the fierpollinsen generating electrodes those electrodes positioned the higher positive potential, 5 'lectric connect to the display and to Fejenigen which guide the lower positive potential to allow charging the ion electron beams.

The invention is explained in more detail using exemplary embodiments with reference to the drawing

F i g. 1 a ^e Color reproduction CRT, hereinafter briefly referred to as color picture tube,

Fig.2 before explanation of the beam path in the Quadrupole lens,

F i g. 3 shows a first embodiment of a color picture tube 15

F i g. 4 shows a second embodiment of a color picture tube;
F i g. 5 some measurement results and

6 shows a third embodiment of a color image

The color picture tube shown in Fig. 1 contains a glass envelope 1, means 2 for producing three Electron beams 3, 4 and 5, a screen 6, color selection electrodes 7 and deflection coils 8. The Electron beams 3, 4 and 5 are in the same plane, namely the plane of the drawing of Fig. 1, and are deflected across the screen 6 with the aid of the deflection coils 8. The screen 6 consists from a multitude of fluorescent strips that light up in red, green and blue, their longitudinal direction to the plane of the drawing the F i g. 1 is vertical. During normal operation of the tube, the fluorescent strips extend in the vertical direction. Fig. 1 thus shows a horizontal section through the tube. The color selection electrodes 7, which on the basis of FIG. 3, 4 and 6 contain a variety of Openings 9 shown in FIG. 1 are only shown schematically The three electron beams 3, 4 and 5 pass through Openings 9 at a small angle to one another and consequently each only meet fluorescent strips a certain color. The openings 9 in the color selection electrodes 7 are therefore very precisely related position on the fluorescent strips of the screen 6

In the now generally used shadow mask tube, the electron beams 3, 4 and d 5 at Passing the openings 9 out of focus. In the aforementioned US Pat. No. 33 98 309, in the openings 9 produced individual lenses for focusing the electron beams. Also it is known the Refocusing with the help of a potential difference between the color selection electrodes 7 and the To effect screen 6, but secondary electrons exert a very disruptive effect.

According to the invention, a quadrupole lens is produced in each opening 9. In Fig. Such a quadrupole lens is shown schematically in FIG. The figure shows part of the color selection electrodes 7 and one of the openings 9. The potential profile along the edge of the opening 9 is indicated 1 ° , _ + _, such that a four-pole field is side. The electron beam passing through the opening 9 is focused in the horizontally drawn plane and focused in the vertically drawn plane, as a result of which the EleitroneXk 10 is generated when the screen is exactly in the horizontal focussing point. As will be explained, it is best not to look closely at the

I. 4th

To focus screen 6, whereby a slightly wider electron spot is obtained. It will only be one negligible influence exerted on the focusing when the electron beam the opening 9 below This results in the color selection of the three electron beams 3, 4 and 5 completely the same way as in the known shadow mask tube. Due to the strong focus, the opening 9 but be much larger than in the well-known shadow mask tube, which means that many more electrons enter the screen 6 and a brighter picture will be obtained. the Defocusing in the vertical direction is not disadvantageous because it uses fluorescent strips that are parallel to the longitudinal direction of the spot 10

In Fig. 3, the color selection electrodes 7 consist of two crossing sets of parallel conductors. The horizontally drawn conductors 11 and 12 of the first set are shown. The second set shows the vertically drawn conductors 13 and 14. The conductors 11, 12, 13 and 14 define one of the openings 9 and are insulated from one another with the aid of insulating material 15. The three fluorescent strips belonging to the opening 9 are labeled R (red), G (green) and B (blue) on the screen 6 produce. The horizontal conductors, inter alia 11 and 12, are connected to one another and have a higher potential than the interconnected vertical conductors, inter alia 13 and 14, whereby in each opening 9 the in FIG. 2 four-pole lens shown schematically is generated.

In Fig. 4 shows a somewhat modified embodiment of the color selection electrodes 7, wherein intertwined horizontal and vertical conductors can be used. Are a horizontal ladder denoted at 16, 17 and 18 and some vertical conductors at 19 and 21. The ladder are with the help of Insulating material 22 insulated from one another.

The in the F i g. Color selection electrodes shown in Figures 3 and 4 are fabricated in the following manner: Two Sets of iron wires (the wires are in connection with the shield against the earth's magnetic Field preferably ferromagnetic), which are provided with glass insulation, are based on a teaching pressed against each other or intertwined in the desired manner (Fig. 4). Then the whole thing heated so that the wires with a glass insulation fuse together, but without them are in electrical communication with each other. Then the glass insulation, except on the crossing points, away from the wires to prevent unwanted charging of the glass. This removal can be done with the help of powder jets from both sides, the insulation of the arches Crossing points are in the »shadow« of the conductor, or by spraying an etchant, that reaches the insulation at the crossing points with greater difficulty than the other places.

With a picture tube with color selection electrodes according to FIG. 4 with ladders with a diameter of 0.24 mn and a pitch of 0.80 mm, i.e. a permeability of the color selection electrodes of about 50% the following results are achieved: Be a potential of the screen 6 of 25 kV and one The potential of the vertical conductors of 24.55 kV and the horizontal conductors of 25.45 kV is the focal point

te of the four-pole lenses 18.0 mm in the middle of the screen with perpendicular incidence and 12.7 mm with incidence below 37 ° at the corners of the screen. The distance between the color selection electrodes 7 and the screen 6 is 15 mm in the middle and 10 mm at the edge, as a result of which the focussing point of the four-pole lenses lies just a little beyond the screen. This prevents a so-called focus ring from being visible on the screen. The electron spots are then 0.10 mm wide in the middle of the screen and 0.09 mm at the corners. A suitable width of the phosphor strips R, G and B is then 0.13 mm. The remaining part of the surface of the screen can optionally be coated with a light-absorbing material.

F i g. 5 shows some measurement results obtained with a configuration according to FIG. 4 are achieved in a special measuring tube. The diameter of the conductor was 0.2 mm and the pitch was on average 1.2 mm. The x direction is parallel to a horizontal line »on the screen. In the y-direction the light yield is plotted in arbitrary units, measured with the help of a very small opening in a diaphragm, which scans the screen in the x-direction, and a photomultiplier, which picks up the light let through through the small opening and converts it into a converts electrical signal. It has been measured at a voltage difference between 0 V and 2000 V between the horizontal and vertical conductors, in steps of 250 V. From Fig. 5 clearly shows the very strong focus at 2000 V. At 0 V, only the vertical conductors produce a shadow on the screen and there is a uniformly illuminated spot behind each opening 9. The very steep flanks of the measurement curves show the very slight influence of secondary electrons, which in known tubes with refocusing form a blurred edge around the light spots.

A third embodiment of the color selection electrodes 7 is shown in FIG. They consist here of an iron plate 23 which is provided with the openings 9 and with a large number of vertical conductive strips, two of which are labeled 24 and 25 and which are located between the openings 9. The conductive strips are insulated from the iron plate by means of insulating material 26. The plate 23 has a thickness of 0.15 mm. The insulating material 26, a glass layer, has a thickness of 0.06 mm. The conductive strips are made of vapor-deposited aluminum and have a thickness of 0.0005 mm. The holes 9 have dimensions of 0.56 χ 0.56 mm and a pitch of 0.8 mm, so that the permeability of the color selection electrodes is approximately 50%. With a potential of the screen 6 of 25 kV, a potential of the plate 23 of likewise 25 kV and a potential of the conductive strips 24 and 25 of 23.4 kV, the focal length of the four-pole lenses is 18 mm at normal incidence in the center of the screen and 12 .7 mm at an incidence of less than 37 ° at the edge of the screen. The distance between the screen 6 and the color selection electrodes 7 is 15 mm in the middle of the screen and 10 mm at the edge of the same. The electron spots are then 0.10 mm wide in the middle of the screen and 0.09 mm wide at the corners, and no focus ring is visible on the screen. The width of the fluorescent strips R, G and B is 0.13 mm. The remaining part of the screen can optionally be provided with light-absorbing material.

The screen 6 and the plate 23 are electrically connected to each other and receive their voltage from 25 kV from an external voltage source. The voltage of 23.4 kV applied to the conductive strips 24 and 25 can also be supplied from an external voltage source. It is also possible to use the not to connect conductive strips to an external voltage source, but to the electron beams to be charged. The four-pole field then gradually becomes due to the charging with the electron beams generated in the openings 9, the focusing effect of which has the consequence that the strips 24 and 25 in be hit by the electron beams to a gradually decreasing extent. The final state is there stable and independent of the beam current because very little current is used to maintain the potential the strips 24 and 25 is required.

For this purpose 4 sheets of drawings

Claims (7)

Patent claims: 1.Color display cathode ray tube with means for generating several electron beams, with a screen on which a multitude of fluorescent areas glowing in different colors is applied and with color selection electrodes, which have a large number of openings for Assigning each electron beam to form phosphor areas of a particular color, with in an electron lens is formed in each opening, characterized in that in each Opening a four-pole lens is formed and that all four-pole lenses are oriented in the same way. 2. Cathode ray tube according to spoke 1 with illuminating phosphor areas in the form of parallel Strips, characterized in that their longitudinal direction to the defocus-referencing direction the quadrupole lens is perpendicular 3. Cathode ray tube according to claim 1 or 2, characterized in that the color selection electrodes formed by a grid consisting of two crossing sets of parallel conductors and the conductors are insulated from each other at the crossing points, the conductors of each set are connected to each other. 4. Kaihodenstrahlröhre according to claim 3, characterized in that the two sets of conductors together are intertwined. 5. Cathode ray tube according to claim 1 or 2, characterized in that the color selection electrodes be formed by a metal plate with said openings and with conductive Strips between rows of openings and with conductive strips between rows of openings is provided, wherein the strips are connected to one another and isolated from the plate. 6. Cathode ray tube according to claim 1, characterized in that the quadrupole lenses generating Electrode voltages are fed to an external voltage source. 7. Cathode ray tube according to claim 1, characterized in that of the four-pole lenses generating electrodes electrically connect the electrodes with the higher positive potential Are connected to the screen and the electrodes carrying the lower positive potential of the Electron beams are charged. 50