DE1562027A1 - Electron beam generating system for television picture tubes - Google Patents

Description

Electron gun for. TV picture tubes The invention deals with an electron gun for television picture tubes, the consists of a cathode, which by means of a control electrode surrounding the cathode arranged insulating body is supported. For television picture tubes, both are direct as well as indirectly heated cathodes. The latter have the major disadvantage that their production is outwardly expensive, because the production of such cathodes is very difficult due to its extremely small dimensions. The covering too Such indirectly heated cathodes with oxide mass encounter great difficulties, because these oxide masses on the indirectly heated cathodes, due to their low Dimensions have a low adhesive strength and tend to flake off easily.

Furthermore, a11 have the well-known, directly or indirectly heated cathodes of television picture tubes for television receivers too long heating-up time, so that sound and picture cannot be received at the same time after switching on. the increasing transistorization. tion of television receivers had the consequence that this Deficiency imm (became more evident and the desire for a TV picture tube that immediately after switching on to reproduce both the sound and the picture when the receiver is ready, more and more urgent charges have been raised.

The invention therefore has the object for television picture tubes to create a cathode whose heating time is so short that in a transistorized TV receiver reproduces the picture at the same time as the sound after it is switched on can be. Furthermore, the invention has the object of the above to avoid technical difficulties of the known cathodes un one to create inexpensive cathode compared to the known cathodes.

In an electron gun for television picture tubes, which consists of a cathode which is held by means of an insulating body arranged in the control electrode surrounding the cathode, this is achieved according to the invention in that this insulating body has two leads lying on a diameter of the control electrode, which are fed by a radially extending heating band are electrically conductively connected to each other, which carries a sintered body enriched with one of the known emission masses below the opening of the control electrode. It is considered advantageous that the sintered body consists of nickel powder and has a porosity of about 40-50%. The sintered body preferably has an area of 0.5-0.2 mm2 and a height of 0.2 mm. The following dimensions have proven to be useful for the formation of the heating tape. Length 5 - 9 mm Thickness 0.025-0.10 mm and width 0.10-0.4 mm. According to a further feature, springs, made of titanium, for example, are provided between the supply lines and the heating band, which are pretensioned in the cold state in such a way that they compensate for the thermally induced changes in length of the heating band. It is useful that the heating tape has a heat resistance in the order of 15 kp / mm2 ur .:; more at temperatures between 700o and 80,000, such as, for example, rhenium, ', 7ölfraL: - or rhenium-molybdenum alloys or nickel-tungsten compounds. Advantageously, the springs can also serve as feeds. Farther it may be appropriate that the heating tape connecting the feeds is arched against the control electrode. Advantageously, the heating tape itself can also serve as a feed. It can also be advantageous to design the leads as hollow rivets. According to a further feature, it is provided that the heating band consists of a material of relatively high specific electrical resistance, for example nickel alloys, preferably nickel-chromium alloys (30-201 chromium) or nickel-molybdenum-iron alloys. The arrangement according to the invention has the advantage that it has a short heating-up time, so that television receivers equipped with such cathodes can be reproduced at the same time after being switched on, picture and sound. Furthermore, the beam generation system according to the invention has the advantage that it can be created in a relatively simple and therefore cost-saving manner. Another advantage of the arrangement according to the invention is the accuracy of the spacing between the cathode surface and the control electrode. Furthermore, in the case of the arrangement according to the invention, the spraying of the cathode with emission material is omitted, so that the errors occurring with such cathodes, such as poor adhesive strength and flaking of the cathode material, are avoided.

The invention will now be explained in more detail using the exemplary embodiments in the accompanying drawings: Figure 1 shows in section and in plan view an embodiment example of the arrangement according to the invention. In the figure 1 is with 1 reproduced the Wehnelt cylinder. The insulating body 2 is by means of the aging 3 in the Wehnel t-cylinder 1 attached. The insulator 2 in the direction of the lehnelt cylinder opening with a continuation sentence 2a is provided, carries the hollow rivets ¢. At the Hohlniesen 4 are with their one .End the springs 6, z. B. made of molybdenum attached Your other end is via an intermediate link? with one end of each Heating band 5 connected. Under the Wehnelt cylinder opening 9 is The one enriched with mission mass is located on the heating tape Sintered body 10 o The redc: re ö are firmly connected to the hollow rivets 4 and when cold, so that even when heated the small spacing of e.g. C -? C:: between the upper part of the sintered area and Wehnelt cylinder retained. can be. The one at one rigid fixation of the change in length taking place in the heating tape would lead to a significant change in the distance between the sintered body surface and Wehnel t-cylinder as a result of the flexing of the belt to lead. This zhernisch Ming re change in length is caused by the These are balanced because when heated, they exert a tensile stress on the Exercise heating tape and keep it stretched; old. The heater tape and the sintered body are dimensioned so that with a heating voltage of 4a. , 5 - 2.8 VA - depending on the tube type - the cathode ei # e Operating temperature of 750 ° C. The heating tape has a length of 7.5 mm, for example, a thickness of 0.040 mm and a width of 0.30 mm.

A slightly different exemplary embodiment is in section and in view reproduced in FIG. The same reference numerals are used for the same parts as used in Figure 1. In this embodiment, the bracket 3-for is missing Fixing of the insulating body in the Wehnelt cylinder. That attachment is in this one Embodiment realized by the beads 3a. Furthermore, the extension 2a of the insulating body, 2 omitted. The heater band 10 is in this embodiment held in its teeth by the rectangular springs 6, e.g. made of titanium. In the embodiment shown in Figure 2, the power is supplied through the rivets 4, which also hold the springs 6 bent at right angles. However, these springs 6 can also be rigid with the insulating body 2 by fritting get connected. When fritting these springs, care must be taken to ensure that these Springs are pre-tensioned when cold, so that they are when the heater strip is heated up Hold the sintered body in a precisely defined position and the set Ensure a small cathode-Wehnelt distance. The voltage is supplied Depending on the structure, either via the rivets 4 or directly via the springs that have been inserted 6th

A slightly different embodiment is in section and in plan reproduced in FIG. 3. Also in this embodiment are again the same reference for the same parts. characters used. In this embodiment the heating band 8 is firmly connected directly to the insulating body 2. In this embodiment FIG. 3, the heater band is fastened by welding in one Hollow rivet 4. In order to avoid a. different installation of the heater on the rivet and different cathode temperature caused thereby is provided that To fill cavities, e.g. with magnesium. Since there is no tensile stress on the heater strip 8 is exerted by springs, a material smaller can be used for this embodiment Heat resistance and higher specific electrical resistance are used will.

M aterials of high electrical resistance are e.g. nickel alloys. Because of this higher electrical resistivity is it is possible to unite the heater band without significant impairment of the heating performance larger cross-section (e.g. 0.3 x 0.905 mm), whereby the expected The service life of the cathode is considerably extended. Expectations

Claims (17)

1. Electron gun for television picture tubes that consists of consists of a cathode, which by means of a control electrode surrounding the cathode arranged insulating body is supported, characterized in that this insulating body has two leads lying on a diameter of the control electrode, which electrically conductively connected to one another by a radially running heating band are, the one below the opening of the control electrode with one of the known Emission mass-enriched sintered body carries. ?. Electron gun according to claim 1, characterized in that the sintered body is made of nickel powder and has a porosity of about 40-50%. . Electron beam generation system according to claim 1 or 2, characterized in that the sintered body is a surface of 0.5-0.2 mm 2 and a height of about 0.2 mm. . Electron gun according to any one of claims 1 to 3-. characterized in that the heating tape is approximately has the following dimensions: length: 5 to 5 mm, thickness: 0.025 to 0.100 mm and Width: 0.10 to 0.4 mm. . Electron beam generating system according to one of the claims 1 to 4 characterized in that between the feeds and the heating tape Springs, for example made of titanium or molybdenum, are provided, which in the cold state are in such a way are biased so that the thermally induced changes in length of the heating tape balance. . Electron beam generating system according to Claim 5, characterized in that that the material of the heating tape has a heat resistance in the order of magnitude of 15 kp / mm2 and more at temperatures between 700 and 800 ° C, such as with rhenium, Rhenium-tungsten or rhenium alloys or nickel-tungsten compounds ° 7. Electron gun according to claim 5, characterized in that the Feathers also serve as feeders. B. Electron gun according to one of claims 1 to, characterized in that the feeds connecting heating tape is arched against the control electrode. 9. Electron gun according to claim 8, characterized in that the heating tape itself as feeds serves. 10 .. electron beam generation system according to one of claims 1 to 6, 8, 9, characterized in that the leads are hollow rivets. 11. Electron beam generating system according to claim 8 or 9, characterized in that the heating tape is made of a material of relatively high specific electrical resistance, such as that of Nickel alloys, consists, preferably nickel-chromium alloys (30 to 20; ö chromium) or nickel-molybdenum-iron alloys, whereby the i :: aterialien have a high temperature resistance do not have. 12.'Llektronenstrahleproduunss ;; system according to claim 11, characterized in that the tape is under a defined tensile stress where the r @ er t the 'ugs anr # ug between 0.5 -... 3 p depending on the technological: : The service life of the belt is: 13. Elek tronenstrahlzeugungssys Sem according to claim 11 and 12, dadurc marked:> net, that as an emission carrier a disk-shaped or roast; .chen-shaped; aihoden material with a thickness of 50 ... 150 #im is used, whereby the attachment of the emission carrier on the heater band by point cutting or Soldering is done in such a way that there is no alloying or diffusion of the two to be fastened Materials done n - w. is negligible. 14 .. ylentron central generating system according to claim 10, characterized in that the hollow rivets prevent rotation mechanical Shaping or chemical treatment (e.g. cementing or frits) are secured, or that instead of the hollow rivet, a suitably shaped Solid material is used. 15. Electron gun according to claim 1 to 6, 8, 99 11, 12 and 13, characterized in that the insulating body for guiding the tape is provided with a groove which can also be used as a cathode grid 1 spacer. 16. Electrode gun according to Claim 15, characterized in that the distance between the cathode and grid 1 is made by one or more spacer rings. 17. Tin electron beam generation system according to claim 5, characterized in that the springs are made of bimetal are, whereby a thermal expansion compensation is achieved.