DE1789103A1 - Cathode arrangement for a cathode ray tube - Google Patents

Description

Cathode arrangement for a cathode ray tube The present invention relates to a cathode arrangement for a cathode ray tube with a tubular cathode which has an emissive surface at one closed end and with a support sleeve arranged coaxially with the cathode and connected to it. In the known cathode arrangement of this type, the tubular cathode and the cathode support sleeve are connected along the entire circumference by a flanging. These known cathode arrangements, however, tend to permanent deformations when the associated tube is switched on and off, which results in an undesired change in the distance between the cathode and the grid of the tube and thus in a change in the tube properties. The present invention is accordingly based on the object of specifying a cathode arrangement in which no permanent deformation occurs during operation and the distance between the cathode and the grid does not change.

According to the invention, this object is achieved in a cathode arrangement of the type mentioned at the beginning is solved by the fact that8 that of the emissive Surface facing away from the end of the support sleeve on the cathode, which has a smaller diameter than the support sleeve has, with several, circumferentially spaced and following is attached internally to the cathode extending indentations.

In such an arrangement, the connection between the tubular The cathode and the support sleeve are so flexible that the tube is switched on and off occurring thermal expansions were added without permanent deformation of the material can be, in addition, the heat dissipation from the cathode is low, so that the Heating power can be kept small and the cathode quickly turns on its Operating temperature reached.

Further developments and refinements of the invention are set out in the subclaims marked.

An embodiment of the invention is described below with reference to the The drawings are explained in more detail, in which: FIG. 1 shows an axial sectional view of parts a shadow mask color television picture tube, the cathode assemblies according to one embodiment the invention includes; FIG. Z shows a perspective on a larger scale than FIG shown view of an electrode, as they are included in the beam generation systems the cathode assemblies of the tube of Figure 1 can be used; Fig. 3 a enlarged sectional view in a plane 3-3 of FIG. 1; . Fig. 4 is an enlarged Sectional view in a plane 4-4 of FIG. 3; and Fig. 5 is an enlarged View of part of Fig.3. In Fig. 1 is a shadow mask color television picture tube shown, the a cathode assembly according to an embodiment of the invention contains. The tube 10 has a piston with a neck 12 that is three symmetrical around the central axis of the tube contains beam generating systems, one of which only two can be seen in FIG.

The three beam generating systems each contain a cathode arrangement 26, a control grid 27, a screen grid 28, a focusing electrode 29 and an anode 30, which are held on three insulating support rods 32. The cathode arrangement 36, the control grids 27 and the screen grids 28 are attached to the rods 32 via molded-on strip-like tabs 42, as will be explained in more detail with reference to FIGS. 2, 3 and 4.

The cathode assemblies contain filaments 48 divided by a annular strips 50 are supported, which in turn on the support rods 32 is attached.

Fig. 2 shows the screen grid 28 of a system, the shape of which is also for the control grid 27 and a support plate 70 (Fig. 4) of the cathode assembly 26 is typical. The screen grid includes a sector-shaped plate 60 with a Opening 62 for the electron beam, which is formed by an annular bead 64 concentrically is surrounded. The sector-shaped plate 60 is essentially straight by two Edges 66 and a curved edge 68 limited, but which latter also completely or could be partially straight. At the straight edges 66 put those with the plate 60 one-piece tabs 42 which are perpendicular to the plane of the sector-shaped Form mounting strips running along the plate. The tabs 42 extend over the curved one outer edge 68 of the sector-shaped plate 60 and run into several ends whose shape is anchoring the tabs in the support rods 32 relieved.

The control grid 27 corresponds to the screen grid 28 with the exception the size and shape of the opening for the cathode ray. The cathode support plate 70 differs from the grid electrodes 27 and 28 mainly in that the sector-shaped Plate 60 has a large opening to accommodate the cathode instead of the small opening 62 and the annular bead 64 is provided. The cathode support plate 70 can also be on the whole smaller than the grid electrodes 27 and 28 so that they are in the control grid 27 can be nested, as will be explained with reference to FIGS. 3 and 4 will.

In the case of a three-beam tube, the straight edges 66 form the cathode support plate 70 and the grid electrodes 27 and 28 form an angle of approximately 120o with one another. Three Similar electrodes, e.g., the cathode support plates 70, can therefore be used as a The crowded, compact arrangement can be assembled, as shown in Fig. 3 is shown.

In the case of an arrangement with four beam generating systems, the form the Sector-shaped plate delimiting straight edges at an angle of about 90o with one another etc.

The cathode arrangements shown in more detail in FIGS. 3, 4 and 5 26 each contain one of the sector-shaped perforated cathode support plates 70, a cathode support tube 72 and tubular cathodes 74. The sector-shaped plane Plate 60 of the cathode support plates each have a large opening 76. the Cathode support sleeves 72 each have an outwardly reaching and in the axial direction stepped radial flange 78 and extend through the openings 76, the outer part of the flange 78 rests against the associated sector-shaped plate 60. The cathodes 74 are tubular and have an end wall 80 with an emissive Cover is provided. The cathodes 74 are concentric to the Support sleeves 72 with the open end at the distal end of the support sleeve. Like on Best seen in Figures 4 and 5 is the distal end of the support sleeve 72 provided with three indentations 82 symmetrically arranged in the circumferential direction, which extend radially inward and engage the tubular cathode 74. the The cathode 74 is welded to the support sleeve 72 at the inner ends of the indentations 82.

T he cathode sleeve 74 is preferably made of a metal with good Emissivity, e.g. made of nickel or an alloy with a high nickel content. the Cathode support sleeve 72 is preferably made of a metal that has poor thermal conductivity e.g. a nickel-iron alloy. The cathode 74 and the support sleeve 72 can thus consist of different metals. When heating the cathode assembly During operation of the tube, the cathode 74 may expand in the radial direction stronger than the cathode support sleeve 72. As a result of the holding of the cathode through however, the indentations 82 are at the junction of the present arrangement Cathode with the support sleeve is very flexible. The cathode support sleeve can therefore be with you expanding cathode 74 are deformed radially outward without the elastic limit the support sleeve is exceeded. When the cathode cools down, the support sleeve takes up returns to its original shape.

In cathode arrangements in which the cathode support sleeve on the circumference is continuously crimped - in contrast to the spaced-apart indentations with the present arrangement - there is, however, the risk that the cathode will die Cathode support sleeve stretches beyond the elastic limit, so that a permanent deformation occurs and the distance between the cathode and grid is undesirably changed will.

3 and 4 show the nesting of the cathode support plate 70 with the control grid 27. Fig. 3 shows most clearly that the Cathode support plate 70 is slightly smaller than the control grid 27, so that it is in the control grid can be nested. This arrangement of the electrodes enables the corresponding nested elements of the beam generating systems in close proximity To be arranged back to back distance to each other. This allows small gaps the axes of the three systems reach each other, resulting in a compact structure of the Allows beam generating arrangement 22 in the lateral direction.

The novel shape of the control grid 27 and the cathode support plate 70 also saves space in the axial direction, contributes to the stiffening of both electrodes and ensures good thermal insulation of the cathode. As a result of the cupless Shape of the control grid 27 can be the cathode support sleeve on that of the emissive End face 80 adjacent end are supported by relatively short supports that are anchored in the rods 32. If you hold the cathode support sleeve at this end, becomes the length of the heat conduction path between the emissive end 80, the is at the emission temperature, and the point at which the thin-walled Support sleeve 72 is attached to the relatively massive support plate 70, maximum. The distance along tubular cathode 74 and then back along the support sleeve 70 ensures good thermal insulation of the emissive end 80 from those Parts of the beam generation system, such as the support plate 70 and the support rods 32, which act as heat sinks and can dissipate heat from the cathode 74. Of the The cathode structure is mechanically rigid because the support strips 42 are attached to the cathode support plate 70 are short and extend directly to the support rods 32. With a cup-shaped The control grid would need the support strips from the cathode support plate 70 one piece in the axial direction along the cathode assembly 26 and around the open end of the cup-shaped Grid electrode run.

From Fig. 4 it can be seen that the cathode support plate '70 and the Control grid 27 are nested one inside the other and with their molded fastening tabs 42 towards extend to the pinch-foot end of the tube 10, whereas the screen grid 28 is axially reversed. The integral tabs 42 of the screen grid 28 thus extend in the direction of the screen Tube. The sector-shaped plates 60 of the control grid 27 and the screen grid 28 face each other with their front sides at a close distance.

Fig. 4 also shows most clearly the differences in the shape of the sector-shaped Plate parts 60 of the cathode support plate 70, the control grid 27 and the screen grid 28. The control grid 27 is provided with an opening 84, the dimensions of which as that of the opening 62 in the screen grid 28 is of the order of magnitude of the beam diameter lies. In the illustrated embodiment, however, the opening 84 is the control grid slightly smaller than the screen grid opening 62, it is also embossed. More precisely, the part of the plate 60 surrounding the opening 84 is somewhat thinner, than the rest of the plate. In contrast to the jet openings 62, 84, the opening is 76 in the cathode support plate 70 is considerably larger, so that it is the cathode support tube 72 can accommodate.

The annular bead 64 of the screen grid 28 extends in the direction on the focusing electrode 29, so that between the screen grid 28 and the focusing electrode 29 a cup-shaped convergent electrostatic field prevails. This field pre-focusses the electron beam coming from a first crossover point in diverges in the vicinity of the screen grid opening 62. As a result of this pre-focusing of the Beam can adjust the strength of the main focusing lens between the electrodes 29 'and 30 can be made smaller, and the beam diameter in the main lens reduced so that the lens defects become less effective, further reduced the beam diameter in the deflection center, so that the color purity tolerance increased when the system is used with a multicolor mosaic phosphor screen. the Bead 64 of the control grid 27 has two; Tasks: She shields the area between of the emissive cathode surface 80 and the control grid opening 84 against electrical Stray fields. Such stray fields can come from the connections of the socket pins to the screen grid 28 or the focusing electrode 29. The bead 64 of the control grid 27 also shields parts of the support rods 32 from metal from the cathode tube 74 evaporates, from. This vaporizing metal could otherwise affect the insulating Knock down the support rods 32 and remove the insulation between the electrodes or lead to shunts. If the bead of the control grid were not there, so this must be cup-shaped @ in order to provide the desired shielding against To reach stray fields or evaporating metal. In this case, however, would the cylindrical wall of the cup-shaped control grid as in the known arrangements stand in the way of holding the cathode support tube 72, as explained above.

Claims (4)

Claims 1. Cathode arrangement for a cathode ray tube with a tubular cathode that has an emissive at one closed end Has surface, and with a coaxially arranged to the cathode and with this connected support sleeve, d u r c h e k e n n n e i c h n e t that that of the emissive Surface facing away from the end of the support sleeve (72) on the cathode (74), which has a smaller Has diameter than the support sleeve, with several spaced apart in the circumferential direction and is attached to indentations (82) extending inwardly toward the cathode. 2. Cathode arrangement according to claim 1, d a d u r c h g e k e n n z e i c h n e t, that the indentation (82) of the support sleeve (72) on that of the emissive surface (80) distal end of the cathode (74) are attached. 3. Cathode arrangement according to Claim 1 or 2, d a -d u r c h g e k e n n z e i c h n e t that the support sleeve (72) on the side facing away from the indentations (82) with a radially outward Reaching mounting flange (78) is provided. 4. Cathode arrangement according to claim 3, in which the cathode and the support sleeve forms one of several corresponding electrode arrangements, dadurchgekennzeic hn et that the fastening flange (78) forms part of a sector-shaped plate (60) which is connected to at least one further sector-shaped plate of another electrode arrangement is arranged around a common axis and attached to the sector-shaped plates on common support rods (32).