DE10118652A1 - Cathode ray tube has electrode system with first control grid in form of flat metal plate held in bearer structure in self-supporting manner separately from second control grid - Google Patents

Abstract

The device has an electrode system in which at least one cathode (KA), a first control grid (G1) and a second control grid (G21) are held in defined relative positions in the beam direction in an insulating common bearer structure. The first control grid is in the form of a flat metal plate and is held in the bearer structure in a self-supporting manner separately from the second control grid.

Description

The invention relates to a cathode ray tube according to the preamble of Pa claim 1.

The construction of a beam system of a cathode ray tube with an electro consequently cathode, grid1 and grid2 and possibly further electrodes, in particular special a focus electrode and an anode, is the common state of the Technique, often using the grid2 electrode in two separate, in electrons Electrodes grid21 and grid22 spaced apart in the beam direction on different Chen potentials is divided.

The imaging properties of an imaging such electron beam tube depend largely on the maximum for a given tube structure possible light-dark shift keying speed of the beam intensity, which like which is determined by the maximum modulation frequency to the beam intensity control modulated electrode voltage. The modulation frequency is particularly limited by that for the modulated electrode voltage effective capacity. In the originally common cathode control Control of the beam intensity is only the electrode voltage of the Ka modulated against reference potential. The grid 1 electrode lies on con constant potential.

Higher modulation frequencies can be achieved by push-pull control at which the electrode voltages of the cathode and the grid 1-  Electrode can be modulated in push-pull, taking the maximum voltage values of the electrode voltages against the reference potential are lower in each case than the cathode voltage required for the same brightness dynamics at the pure cathode control. Maximum span is typical, for example voltage amplitudes for grid 1 and cathode of -50 V and + 50 V for Ge Genetic cycle control compared to 100 V in the cathode control.

Another option for beam intensity control is pure git ter1 control, in which the electrode voltage of the grid 1 electrode mo is dulated and the cathode is at constant potential.

DE 198 57 800 A1 describes such a cathode ray tube with a one Grid1 sleeve surrounding the cathode support assembly, the grid2- Electrode surface facing electrode has a recess which with a cup-shaped cover arched over the edge of the recess a central beam opening is bridged.

EP 0 809 853 B1 shows a cathode ray tube for producing three separate electron beams. There is a common grid 1 control electrode pot-shaped and the three cathode arrangements are in the grid 1- Pot held, which in turn with glass rods one with subsequent ones Electrodes common support structure is firmly connected.

From DE 30 10 807 a cathode grid arrangement is known, in which an electrode group consisting of cathode, first control grid and second control lattice is prefabricated as a firmly connected assembly, which is an assembly plate for attaching the module to other electrodes of an electrical system cannon common glass rods.  

DE 196 30 200 A1 describes a cathode ray tube in which Blasting system a sandwich sub-module with first and second control grille between ceramic discs over a ceramic spacer ring with a Holder of a cathode support assembly is connected.

It has been shown in practice that the multiple use of the compound ke Rami components with each other and with metallic components into one complex electrode module through the various connection techniques is complex and unsatisfactory.

The present invention has for its object a cathode ray specify tube with further improved structure of the blasting system.

The invention is described in claim 1. The subclaims ent hold advantageous refinements and developments of the invention.

The invention reduces compared to the Ka known from DE 198 57 800 A1 cathode ray tube in particular the capacitance between them radially opposite standing metallic surfaces of grid1 as the first control grid and Katho de as well as between grating 1 and one typically the beam system vice versa metal shield that is at ground potential.

The design of the first control grid, hereinafter also the grid 1 electrode called, as a flat metallic disc, in particular as a sheet metal part in a manner known per se for electrodes of such a beam system compared to e.g. B. metallized ceramic electrode carriers inexpensive Manufacturing with high precision and reproducibility. By the second Control grid self-supporting separate bracket in the support structure is not required Manufacturing processes with extra connection techniques. The relative orientation  of the plurality of electrodes, preferably including the focus electrode and An ode, can advantageously in one step, in particular by melting zen outer sections, holding webs etc. of the electrodes in glass rods of the ge common support structure.

The grid 1 electrode advantageously has a recess, as is known per se tion, which is due to an aperture of lower material thickness, in particular a cup-shaped, arched cover is spanned. The height of the grille 1- Electrode is preferably less than 20%, in particular less than 10% their largest diameter or in absolute terms less than 2.5 mm, ins especially less than 1.5 mm.

While in the arrangement known from DE 198 57 800 A1 the sides walls of the grid 1 pot as a centering for a cathode support arrangement such a centering takes place in the inventive Cathode ray tube advantageously by means of a separate centering arrangement voltage, in which the cathode support arrangement in the direction of the beam axes is guided. The centering arrangement is advantageously independent gig of the first control grille on the common support structure of the several fixed electrodes. The centering arrangement can be advantageous in a first Embodiment as a circular cylindrical sleeve, in particular metallic on con constant potential. The centering arrangement can also reduced to at least three polar individual tours.

To adjust the distance between the cathode and the first control grid preferably an insulating spacer in the cathode support assembly inserted between a cathode support and the first control grid. The Cathode support arrangement is advantageously based on a small Spring preload against the first control grille. The first control grille  can, possibly in addition to the cup-shaped bulge of a beam diaphragm in egg ner recess, a step or ramp in the radial direction in the radial direction have which can have a shape-stabilizing effect.

The invention is based on a preferred embodiment illustrated in detail with reference to the figures. because at shows

Fig. 1 shows a structure of a beam system according to the invention

Fig. 2 shows a detail of the beam system of FIG. 1

The beam system sketched in Fig. 1 comprises as electrodes a cathode KA, a first control grid G1, also referred to as grid1, a second control grid arrangement, also referred to as grid2, which in two grid sub-electrodes with a sub-electrode G22 and the first control grid The sub-electrode G21 facing G1 is divided. In the following, only the grid G21 is designated with two control grids.

Several, preferably three, regularly arranged around the beam axis Hal test rods HS, preferably made of glass, serve as a common support structure for the electrodes G22, G21 and G1 and possibly other electrodes of the beam system such as. B. a focus electrode FO and an anode AN. The metallic electrodes are held in an assembly auxiliary device in precise mutual alignment and melted with their outer edges, via radially outwardly directed holding tabs HF or the like in the holding rods HS and are then fixed in their mutual positions via the supporting structure. FIG. 2 shows the detail marked in FIG. 1 in a more detailed representation.

The essentials of the electron beam tube according to the invention the prior art with all-metal grid1, z. B. according to DE 198 57 800 A1 or EP 0 809 853 B1, is the flat design of the grid 1 electrode G1 as a flat or preferably stepped metallic disc, in particular as Sheet metal part. The grid 1 electrode is thereby galvanically centered direction decoupled for the cathode arrangement and shows in the flat version tion an advantageously small capacity against the cathode sleeve and against one typically surrounding the control electrode system, to ground po shielding. At the same time, such a grid 1 electrode is as Sheet metal part can be produced inexpensively and with reproducible high precision. The Height H1 of the grid 1 electrode is advantageously less than 20%, ins especially less than 10% of the largest diameter D1 of this electrode (H1 <0.2 D1) and / or less than 2.5 mm, in particular less than 1.5 mm.

A cathode support arrangement in which the cathode is held is internal half a centering arrangement, which, for. B. as a circular cylindrical centering sleeve ZH is executed, held and advantageously in a small amount in Beam direction guided and preferably under the influence of a Spring force in the direction of the beam axis is applied to the grid1 electrode G1. The cathode support arrangement can, for example, as shown, a support disc TR, with which the cathode sleeve KH with the cathode KA and the Any existing cathode heater HE is firmly connected, and a distance ring DR between the carrier disk TR and grid 1 included. In the sketched case are still an adapter ring AR as an intermediate piece between the inside diameter of the centering sleeve ZH and the smaller diameter of the Trä gersscheibe TR and a support sleeve SH, via which one of ver limited tabs LA applied spring force in the direction of the beam axis on the carrier disk TR and the spacer ring DR as a weak pressure force on the Grid1 electrode G1 is transmitted. A spring force can also be achieved by a  separate compression spring can be applied. Such a spring force is one high constancy of the axial distance from cathode KA to the beam diaphragm SB1 ensures that there is no thermal stress occur between grid 1 and cathode. The sleeve SH can be in another version tion are also firmly welded to the centering sleeve, in particular by means of Laser welding. A secure contact of the ring DR on the grid 1 electrode can, for example, by an additional spring arrangement between SH and TR or solely by the elasticity of the grid 1 electrode after the initial Press the carrier ring TR or the spacer ring DR during assembly to be given.

The grid 1 electrode G1 is preferably white in its radial course se not just stated that the axial distance to the second tax electrode G21 enlarged with increasing distance, preferably in the form of we at least one level. The sections of the electrode are preferably in front of and after such a stage essentially flat with perpendicular to the beam axis SA lying levels.

An inexpensive stage of this type can be described in DE 198 57 800 A1 per se known pot-shaped bulge given a central beam aperture SB1 his. An advantageous embodiment sees one from the beam diaphragm separated stage ST in the radial course of the grid 1 electrode between an in inner ring section and an outer ring section GR12 in front. Such a step ST is advantageously in a radius range of a maximum of ± 20% of the largest electrode radius D1 / 2 around the contact surface of the Cathode support arrangement on the grid 1 electrode and increases the mechani cal stability of the flat grid 1 electrode against a preferably given ne light pressing force with which the cathode support arrangement axially against the grid1 electrode is pressed.  

The centering arrangement is preferably mechanically independent of the Git ter1 electrode independently with the common support structure, for. B. the Hal test rods HS is connected and is galvanically separated from the grid 1 electrode in metallic execution. In FIG. 2, such a centering arrangement is provided as a circular-cylindrical metal sleeve of the cathode ray tube is advantageously on kon stantem potential, particularly ground potential. The circular cylindrical shape is preferred because of the simple and precisely producible geometry, but not mandatory. The centering arrangement can also have, for example, several separate, individually arranged, polar guides about the beam axis with guide surfaces parallel to the beam axis. In the case of a metallic design of the guide surfaces, the area which determines the capacity of the cathode sleeve against such a centering arrangement is reduced compared to a closed circular-cylindrical shape by such segmentation. The centering arrangement can also be non-metallic.

The grid 1 electrode and the cathode are preferably separated, in particular special control voltages modulated in push-pull. feed for the sake of clarity, the individual electrodes are shown in the figures not shown.

The execution of the grid 1 electrode as a flat, all-metal disc enables light cost-effective and reproducible with high precision a mechanically stable electrode, in particular as a sheet metal part, with a advantageously low capacity in the beam system of the cathode ray tube. A non-level course at the ST level can e.g. B. by deep drawing a flat sheet are generated.  

The above and those specified in the claims as well as the Figil Features that can be extracted are both individual and in different Combination can be advantageously implemented. The invention is not described on the NEN embodiments limited, but within the scope of professional Can be modified in many ways.

Claims (14)

1. cathode-ray tube with an electrode system, in which at least one cathode (KA), a first control grid (G1) and a second control grid (G21) are held in defined insulating positions in an insulating common support structure (HS), characterized in that the first control grille (G1) is designed as a flat metallic disc and is held in the supporting structure in a self-supporting manner separate from the second control grille. 2. A cathode ray tube according to claim 1, characterized in that the The height (H1) of the first control grille (G1) is less than 20% in particular re less than 10% of its largest diameter (D1). 3. cathode ray tube according to claim 1 or 2, characterized in that the height of the first control grid is less than 2.5 mm, in particular the less than 1.5 mm. 4. A cathode ray tube according to one of claims 1 to 3, characterized records that the first control grid (G1) in the radial direction a Stu fen course with at least one level (ST) and on both sides of the level Flä Chen sections (GR11, GR12), which is essentially flat are. 5. A cathode ray tube according to one of claims 1 to 4, characterized shows that the first control grid (G1) consists of an outer ring (GR11, GR12, ST) with a recess around the cathode and a recess tion spanning beam aperture (SB1) is composed, the The material thickness of the beam diaphragm is less than that of the outer ring.   6. A cathode ray tube according to claim 5, characterized in that the Beam aperture (SB1) is cup-shaped. 7. cathode ray tube according to claim 5 or 6, characterized in that the outer ring has a step (ST) in the radial direction. 8. A cathode ray tube according to claim 7, characterized in that the Step (ST) with increasing radius from the second control grid (G21) is directed away. 9. cathode ray tube according to one of claims 1 to 8, characterized records that a cathode support assembly carrying the cathode under Spring tension is supported against the first control grid. 10. A cathode ray tube according to claim 9, characterized in that the Cathode arrangement in a centering arrangement (ZH) in the beam direction is guided. 11. A cathode ray tube according to claim 9 or 10, characterized in that that the first control grid (G1) is independent of the cathode support order or the centering arrangement is held in the support structure. 12. A cathode ray tube according to one of claims 1 to 11, characterized ge indicates that the support structure several on the outer circumference of the two ten and first control grid, the cathode support arrangement and possibly white tere electrodes arranged around the beam axis, essentially Includes holding struts running parallel to the beam axis.   13. A cathode ray tube according to one of claims 1 to 12, characterized ge indicates that the cathode and the first control grid are separated against Mass modulatable control voltages can be applied. 14. A cathode ray tube according to one of claims 1 to 13, characterized ge indicates that the electrode system from one to ground potential shielding are surrounded.