NL8000814A - ELECTRON GUN WITH LOW COAT GRID CAPACITY. - Google Patents

Description

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80 3045 / Ti / AA / asm n%

Applicant j Tektronix, Inc. 4900 $ .W, Griffith Drive,

Beaverton, Oregon 97005, United States of America.

Short designation: Electron gun with a low cathode grid capacity.

In high-frequency electron discharge units such as cathode-ray tubes, in the capacitance formed between the control grating and the acceleration grating of an electron gun, a small surface area must face the other electrodes in the electron gun 5 in order to reduce the input capacitance and the high-frequency signal for high-frequency operation to the control grid.

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U.S. Pat. No. 2,458,962 describes a cathode ray tube grating system having first and second frusto-conical lattice members. The first grating section is placed close to the cathode and the second grating section is placed within the first grating section with an inner part separated therefrom.

This version gives a large surface area, which increases the capacity; it is not suitable for high frequency cathode ray 15 tubes.

The grating system of U.S. Pat. No. 2,540,621 has a similar construction to that of U.S. Pat. No. 2,458,962 except that the first grating portion is not in the shape of a truncated cone; however, the opposing metal surfaces of the first and second grille parts are large, so that the larger capacity makes this grating design unsuitable for high-frequency operation.

The grating system of U.S. Pat. No. 2,443,916 has a small first grating welded to an eye which connects the first grating portion to a ceramic mounting portion and upon which the second grating portion is also separated 8000814

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-2- ναη the first grille part is mounted.

This embodiment gives a large surface area, resulting in a large input capacity, which is a great disadvantage in high-frequency operation.

The invention relates to electron discharge units and in particular to an electron gun having an improved low-capacity grating system for high-efficiency cathode ray tubes.

According to the invention, a small diameter control grid is secured to a flat inner surface of an annular TO ceramic portion and a flat outer portion of a focusing grid with an outer surface of the ceramic portion. The ceramic part in the shape of a truncated cone has a different outer surface and the acceleration grille has an inner flat part lying near the control grille, the outer and inner flat parts of the acceleration grille being connected by means of a truncated cone part along the truncated conical surface of the ceramic part. The surface of this grid design results in a small input capacity, as a result of which high-frequency signals can also be fed to the control grid. The spacing and alignment of the grids relative to each other and to the cathode is very close and the openings in the grids are made therein after the grids have been covered with the ceramic. are connected so that their placement is very accurate. The cathode grid system is mounted via the gear grille attached to the mounting disc.

The object of the invention is to provide a low-capacity grating system as part of an electron gun for a tatode-ray tube, which further has a small surface area to reduce the input capacity, wherein the grating parts are positioned very accurately with respect to each other and the cathode with respect to the grating parts the cathode grating system is mounted via the gear grating part in a cathode ray tube as part of the electron gun, and the apertures in the 8000814% - 3 -? gratings after the adhesion of the gratings on a ceramic part are formed.

The invention will be elucidated on the basis of the drawing:

Fig. 1 is a perspective view of the cathode grid 5 system of the invention; and Figure 2 is a cross-sectional view taken along line 2-2 in Figure 1.

As shown in Figs. 1 and 2, a cathode grating assembly 10 has an annular ceramic portion 12 connected to its inner surface with an inner flat surface 16 of another ceramic portion 14 by brazing. In the center of the ceramic portion 14 there is an opening 18 and it has a control grid portion 20 of slightly larger diameter than the openings 18 and is bonded close to the inner surface 16.

The grating section 20 is preferably soldered to the inner surface 16, with solder along the entire periphery of the grating section 20 or at discrete locations along it. The grating part 20 consists of stainless steel with a thickness of 0.13 mm and containing an opening 22 with a diameter of 0.55 mm.

Notches 24 are provided in the upper surface of the ceramic portion 12, which portion is soldered to the surface 16 to guide the grid wire 20 from its connection to the control grid portion 20 outside the array 10. The wire 26 is a thin wire and has a diameter of 0.2 mm and thereby gives a high inductance and a low capacitance.

The keranic portion 14 has an outer spot surface 28 and an outer surface 30 in the form of a truncated cone. A gear grille portion 32 has an outer flat portion 34, an inner flat portion 36, and a truncated cone portion 38 connecting the portions 34 and 36 together. The portion 34 is soldered to the flat surface in the same manner as the grating portion 20 is connected to the inner surface 16 to position the grating portion 32 on the ceramic portion 14. The portion 38 substantially corresponds to the arrangement of a frusto-conical surface 30 8000814 ~ 4 - s · and the portion 38 accurately positions the portion 36 relative to the grating portion 20 such that the grating portions 20 and the portion 36 of the grating portion 32 run parallel for a distance of 0.55 mm. The portion 36 has an opening 40 carbon black 5 of 0.55 mm in diameter and is accurately aligned with the opening 22. The portion 36 has a smaller diameter than that of the grating portion 20.

To ensure that the openings 22 and 40 are aligned, they are placed in the grating parts 20 and 32 after these grating parts have been spliced onto the ceramic part 14. Openings 22 and 40 are applied to the grating sections with the aid of known electron discharge devices. In this way it is ensured that the openings 22 and 40 are aligned.

A cathode carrier 42 has an inwardly facing flange 44, which is soldered to the bottom surface of the ceramic portion 12. A ceramic disk 46 has a hole 48 in which a cathode tube 5 is bonded to the end of which a cathode cap 52 is provided. The tube 50 is bonded tightly to the ceramic disk 46 by means of guides 54 in the tube 20. The guides 54 are pressed snugly against the surfaces of the ceramic disk 46 to closely enclose the tube 50 therewith.

The ceramic disc 46 rests against the flange 44 and is secured against it by means of the flange 56 of the mop part 58, which is connected to the support 42 by a pressure or welding connection. In this manner, the cathode cap 52 is accurately positioned and aligned with respect to the grating portion 20 and the opening 22.

The distance between the grid part 20 and the cathode cap 52 is 0.06 mm. The cathode cap 52 has a small diameter and the tube 30 50 is long enough to reduce the capacity. A cathode spacer 60 in the form of a metal ring of suitable thickness can be placed between the ceramic disc 46 and the flange 44 to compensate for spacing problems due to solder thickness 8000814-5 and tolerances of the flange 44, the ceramic disc 46 and guides 54 to ensure that the cathode cap 52 is accurately positioned and aligned with respect to the grating portion 20.

Another ceramic disc 62 has a flange rust4 which rests against the underside of the support 42 and is connected thereto by means of tabs 66 which protrude from the outer support 42 and are bent against the disc 62. A filament 68 is located in the tube 50 and its ends are resp. connected to the conductors 10, 70 and 72, which are connected to the ceramic disc 62 by means of rivets 74 in holes 76.

A disk portion 78 is connected to the portion 34 of the lattice portion 32 and has tongues 80 which are connected with glass rods for mounting the cathode lattice array 10 as part 15 of the electron gun

The small diameter of the grating section 20, the small diameter of the section 36 of the grating section 32, the small diameter of the cathode and the small diameter of the grating conductor 26 all give a reduction in capacitance, so that the 20 through the conductor 26 input signals fed to the control grid part 20 can cause the electron beam to operate at very high frequencies without a large load on the grid ·

Because the grating part 32 is connected to the surface 28 of the ceramic part 14 and the grating part 20 to the surface 16, this results in a reduction of the capacity due to the distance between them. The accelerator grid part 32 is connected to a power supply of 200-400 V. · The precise separation and arrangement of the grid parts 20 and 32 with respect to each other and up to the cathode give a higher achievable resolution. If desired, another grid with high inductance 26a and the same size as the conductor 26 can be connected to the grid part 20 and together with the conductor 26 this embodiment can form a transmission line 8000814-6 system for an even higher frequency response

Within the scope of the invention, for example, the ceramic parts 12 and 14 may consist of one part.

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Claims (8)

1. A cathode grating system for use in an electron discharge unit characterized by ceramic means having an annular portion and another portion having an inner flake surface, a flat outer surfaces, outer frusto-conical surface and a central opening; and by a first grating connected to the flat inner surface over the central opening, the first grating having a slightly larger diameter than the central opening and having a through opening, a second grating having an outer portion, an inner portion and a truncated cone section connecting the inner and outer parts, the outer part adhered to the flat outer surface while the inner part disposed within the central opening parallel to the first grating and the truncated cone section extending along the truncated cone surface, and the inner part has another opening which is in line with the opening of the first grid, and by cathode means, which are connected to the ceramic means and which are accurately positioned relative to the first grid. System according to claim 1, characterized in that the connecting means are connected to the outer part of the second grid for mounting the cathode grid system as part of an electron gun. System according to claim 1, characterized in that an opening is present in the ceramic means and that a conductor with high inductance is connected via this opening to the first grid. System according to claim 3, characterized in that other high-inductance conductors are connected to the first grid via the opening. System according to claim 1, characterized in that the inner portion of the second grid has a smaller diameter 800091a c - 8 - than that of the first grid. 6. Method for forming a grating system intended for an electron gun for an electron discharge device, characterized in that a first grating part is attached to a flat inner surface of ceramic means and fixed over a central opening thereof of a flat outer part of a second grating part. to a flat outer surface of the ceramic means such that a flat inner portion of the second grating portion is positioned within the central opening parallel to the first grating portion, and forms openings of the same dianeter in the first grating portion and the inner inner portion of the second grating portion. . 7. Process according to claim 6, characterized in that the adhesion is carried out by soldering the first grating part to the flat inner surface and the flat outer part to the flat outer surface of the ceramic means. 8. Process according to claim 6, characterized in that an electron discharge device is used for the formation of the openings. 8000814