DD238473A5 - SLOTTED MASK ELECTRON CANE FOR CATALYST RADIATION TUBES - Google Patents

Abstract

The invention relates to a slotted mask electron gun for use in a cathode ray tube having a plurality of cathodes arranged in the given order and at a certain distance, a control grid, a screen grid electrode system and at least two main focusing lens electrodes. The aim and object of the invention is to provide a simple producible electron gun with a Abschirmgitter to which a dynamic voltage is applied to reduce the problem of bulge distortion, the unwanted brightness modulation should be as low as possible with known Ausfuehrungen. According to the invention, this is achieved in that the screen grid electrode system comprises two spaced-apart metal parts, wherein at least one of the parts has a plurality of elongated, rectangular slots machined in one of its faces, and wherein the slots have a depth smaller than the thickness of the part and facing the other part, and a plurality of circular apertures communicating with the slots and passing through the part. Fig. 2

Description

Field of application of the invention

The present invention relates to slit-mask type electron guns such as those used in color picture tubes, and more particularly to an improved electron gun having a two-piece screen grid electrode capable of generating an electron beam variable in shape by dynamic modulation.

Characteristic of the known technical solutions

There are several different types of electron guns used in color picture tubes. One embodiment that is currently widely used is the slot mask electron gun. The slot mask electron gun serves to generate at least two and preferably three electron beams in a common plane and the alignment of the beams along convergent beam paths to form a small spot on the screen.

There has been a general trend toward slit color picture tubes having larger deflection angles for shorter tube targets. However, for tubes with a deflection angle of 110 °, it has been found that the electron beams are excessively distorted as they are deflected toward the outer portions of the screen. Such distortions, commonly referred to as lenticular bulges, appear on the screen of the picture tube as unwanted faint shadows, as a trailing effect emanating from a light kernel or spot of desired intensity. Such distortions are due, at least in part, to the effects of edge portions of the deflection fields of the tube deflection yoke on the electron beam during its passage through the electron gun, as well as the nonuniformity of the yoke deflection fields themselves.

As the fringing fields extend into the region of the electron gun, as is usually the case, the rays may be deflected slightly from the axial direction into a more rationed portion of the electron lens of the gun. The result is often a lenticular distortion of the electron beam strike leak that extends from the beam spot to the screen center. This condition is particularly troublesome with tubes equipped with self-converging deflection yokes with ring deflection coils because of the relatively strong fringing fields of the toroidal coils.

The self-converging deflection yokes have uneven fields which cause the electron beams to become increasingly divergent as the horizontal deflection angle increases. These uneven fields also cause a vertical convergence of the electrons within the individual beams. In this way, the beam spots which are located to the right and left of the center of the screen, over-converged in the vertical direction, so that in the vertical direction, both upwards and downwards is lenticular distorted.

The vertical bulges of the round spot to the lens shape, which is due to both the effects of Jochrandfelder in the field of electron gun and the unevenness of Jochfelder is an undesirable condition, which leads to a poor resolution of an image displayed on the screen.

It is known that to compensate for the above-described astigmatism of the beam spot, asymmetrical electron gun electrodes are used which provide for compensating astigmatism in the electron optics of the gun. See, e.g. U.S. Patent No. 4,234,814, which discloses a screen grid electrode having an aperture having a rectangular cross section rearwardly of the cathode and a circular cross section forward of the screen. This astigmatic screen grid consists of one piece from an electrical point of view and is fed with a fixed DC bias during tube operation. While this electron gun sufficiently reduces lenticular bulge astigmatism in some tubes, other tubes still require further correction, particularly with very wide deflection angle tubes, again especially when used for the reproduction of the publication in US Pat Near the corners of the screen should be used.

Also known is a two-piece screen grid electrode comprising a first aperture plate having an elongated aperture extending through the first plate and a second plate having a circular aperture therethrough. Such an electrode assembly is disclosed in U.S. Patent No. 4,319,163. In operation of this electron gun, the second plate is fed with a DC bias and the first plate is fed with a DC bias superimposed on a dynamic signal which is synchronized with the horizontal and / or vertical deflection signals. A disadvantage of this design is that the brightness of the tube is also modulated by the applied dynamic voltage, unless the modulation voltage is very small.

US Pat. No. 4,443,736 discloses a screen grid electrode assembly including a group of three aperture metal plates separated by two electrically insulating parts. The two outer plates have three apertures in series, and the middle plate has at least one elongate aperture which is desirably to extend at least to the outer edges of the two outer apertures of the outer plates. In this electron gun, the two outer plates are electrically connected to the screen grid potential, and a dynamic signal is superimposed on the applied DC voltage. The outer plate adjacent to the control grid electrode ensures that the brightness modulation of the tube is kept as small as possible, although in this patented design, however, a brightness variation in the range of 20 to 30% occurs. For the further reduction of the brightness modulation, it is necessary to apply a counter-modulation voltage to the cathode. The three-platen construction also creates difficulties during the beading process because the distance between the adjacent metal plates must be small.

Object of the invention

Accordingly, it is desirable to provide an electron gun having a shielding grid which applies a dynamic voltage to reduce the problem of bulge distortion and which is easier to manufacture, but which provides at least the same or better result in unwanted brightness modulation than older versions of electron guns patents.

Explanation of the essence of the invention

In accordance with the invention, the slit mask electron gun for a cathode ray tube comprises an improved beam shaping area and beam focusing electrodes. The improved beam region comprises a plurality of cathodes, a control grid, and a novel screen grid electrode system, the parts of which are arranged at a predetermined distance in a dispensed order. The screen grid electrode system is composed of two metal pieces spaced apart from one another and at least one of which has a plurality of rectangular longitudinal slots machined into one of its surfaces. The slots have a depth that is less than the thickness of the metal part, with the slots on the opposite side of the other part. A plurality of circular apertures communicating with the slots and penetrating the metal parts are incorporated therein.

embodiments

In the drawing shows:

Fig. 1 is a schematic elevation (partially in axial section) of a cathode ray tube, which carries the novel electron gun in itself.

Fig. 2 is a longitudinal section partially in section of an embodiment of the novel electron gun according to Fig. 1. Fig. 3 is a plan view of a grid part of the screen grid electrode of the electron gun according to Fig.2.

4 is a schematic representation of a set of typical waveforms of the signals used for the operation of the novel electron gun.

Fig. 5 for certain points of the signal waveform according to Fig.4, which is applied to the screen grid electrode, the corresponding position on the screen of the picture tube.

Fig. 6 is a schematic representation of another set of typical signal waveforms used for operation of the novel electron gun.

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Fig. 7 for certain products of the signal waveform of Fig. 6 applied to the screen grid electrode, the corresponding position on the screen of the picture tubes.

8 is a longitudinal section partially in section of a second embodiment of the novel electron gun according to Fig.l.

9 shows a plan view of the two superposed lattice parts of the screen grid electrode, the lattice parts of which have vertically arranged slots.

Figure 1 shows a color picture tube 8 with a glass envelope 10 comprising a rectangular face plate 12 and a tubular neck 14 connected to a rectangular funnel 16. Panel 12 consists of a screen support 18 and a peripheral side wall 20 which is connected to the hopper 16. A mosaic-type three-color phosphor screen 22 is applied on the inner surface of the face plate 18. Screen 22 is preferably a line screen in which the phosphor lines are substantially perpendicular to the high frequency raster scan of the tube, i. perpendicular to the plane of FIG. 1) extend. A multi-color color control electrode or shadow mask 24 is releasably secured by known means at a predetermined distance from the screen 22. An improved slit-mask electron gun 26, schematically represented by dashed lines in FIG. 1, is mounted in the neck 14 and generates and sends three electron beams 28 along coplanar convergent paths through the mask 24 to the screen 22.

The tube of Figure 1 is to be used in conjunction with an external magnetic deflection yoke, such as yoke 30, which, as shown schematically, surrounds the neck 14 and funnel 16 near its junction. Upon application of voltage to the yoke 30, the three beams 28 are exposed to vertical and horizontal magnetic fields to cause the beams to move across the screen 22 in a horizontal or vertical direction in a rectangular grid. The output plane of the deflection (at zero deflection) is represented by the line P-P in Fig. 1, which leads approximately through the center of the Ablenkjoches 30. Because of the fringing fields, the deflection zone of the tube extends axially from the yoke 30 into the region of the electron gun 26. For the sake of simplicity, the actual curvature of the deflected electron beam paths in the deflection zone is not shown in FIG. An example of a magnetic deflection yoke 30 is a saddle ring yoke (ST yoke - saddle-toroid type yoke) as described in U.S. Patent 4,134,345.

With the exception of the modifications described below, the electron gun 26 may correspond to those three-beam slotted-mask electron guns described in the above-cited U.S. Patent Nos. 4234814, 439163 and 4443736, or the extended-focal length slit mask tubes of the type disclosed in U.S. Pat U.S. Patent 4,370,592. These patents disclose modified designs of the electron gun described in US Pat. No. 3,774,554.

Details of the electron gun 26 are shown in FIGS. 2 and 3. The electron gun includes two glass mounting rods 32 to which various electrodes are attached. These electrodes include three equally spaced in-line cathodes 34 (one for each beam but only one shown), a control grid electrode 36 (G 1), an improved screen grid electrode system 38 (G2a, G 2b), a first main focusing lens electrode 40 (G3). and a second main focus lens electrode 42 (G4) fixed to the glass rods in the order given and at a certain distance. Both electrodes G1 and G4 and the two ends of the G3 electrodes have three in-line apertures, which allow the passage of three coplanar electron beams 28. The structure of the screen grid electrode system 38 will be described below. The electrostatic main focusing lens in the gun 26 is formed between G3, the electrode 40, and G4, the electrode 42. G3, electrode 40, consists of two cup-shaped elements 44 and 46, the open ends of which are secured together. Although G3, electrode 40, is shown as a two part structure, it could be made from any number of parts as well as a single part of equal length. G4, electrode 42, can also consist of two cup-shaped parts 48 and 50, which are fastened together at their open ends. Furthermore, although the main focusing lens is made up of two electrodes, it could also consist of three, four or more electrodes (in this case, voltages other than those shown would be applied).

That portion of the electron gun 26 including the cathodes 34, the control grid electrode 36, and the screen grid electrode system 38 is known as the beam forming area of the gun. This beam region generates electrons and forms therefrom beams that overlap in the vicinity of the screen grid electrode system 38. The main focus lens electrodes 40 and 42 include the beam focusing area of the gun. The beam focusing area builds up an electrostatic focusing field for focusing the electron beams and imaging the beam intersection points on the screen.

A first embodiment of the improved screen grid electrode system 38 includes two spaced-apart metal parts G2a and G2b. The first metal part G 2a, which is adjacent to the control grid 36 (G 1), comprises a substantially flat plate having a thickness of about 0.51 mm (20 mils). As shown in Fig. 3, three substantially identical horizontal slits 52 are incorporated in one of the major surfaces of the first part G2a. The slots 52 are each approximately 0.71mm (28mils) high, 2.03mm (8OmHs) wide, and 0.25mm (10mils) deep. A circular aperture 54 is incorporated in each of the slots 52; they extend through the first metal part G 2a and are aligned with the apertures in the control grid 36 (G 1). The three circular apertures 54 have a diameter of 0.635mm (25mils). The first part G2a is located at a distance of about 0.229mm (9mils) from the control grid 36 (G1). The second metal part G2b has a thickness of about 0.13 mm (5 mils) and is disposed at a distance of about 0.13 mm (5 mils) from the first part G 2a. The second part G2b has three circular apertures 56 having a diameter of 0.635mm (25mils) aligned with the circular apertures 54 in the first part G2a. As shown in Figures 4 and 5, during operation of the electron gun 26, a DC DC voltage is applied to the first portion G 2a to control the beam limitation.

To the second part G2b is applied a DC voltage superimposed on a composite dynamic signal related to the vertical and horizontal deflection. This dynamic signal modulates the cross-sectional shape of the beam in accordance with the deflection, thereby compensating for the above-mentioned lenticular bulge of the otherwise circular beam spot. The dynamic signal connected to the part G2b together with the horizontally arranged slits 52 in the part G 2 a improves the corner brightness and thus compensates (the reduction of /) the edge transmission loss caused by the shadow mask 24.

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The dynamic modulation voltage changes the asymmetrical slit lens power between the first part G2a and the second part G2b of the screen grid electrode system 38, thereby improving the corner resolution without deteriorating the resolution in the screen center. The first part G 2 a, whose thickness is about four times as large as that of the second part, shields the dynamic signal from the area of the control grid 36 (G 1), so that the brightness modulation or -Schwankung to about 3% - compared with about 20 to 30% is reduced in the above-cited U.S. Patent 4,443,736. The low level of brightness modulation achieved with the present design (of the system) eliminates the cathode count modulation required in the prior art electron guns which apply a dynamic modulation voltage to the screen grid. The present screen grid electrode structure is economical because it can be easily manufactured by standard methods for the production of electron guns. On the other hand, the slits may be arranged vertically in the part G 2 a, and then waveforms such as those shown in Fig. 6 may be applied to the part G 2 b. The corresponding points on the screen of the tube are shown in FIG.

A second embodiment of the novel electron gun 26 'is shown in FIG. The electron gun 26 'corresponds to the electron gun 26 described herein, and differs only in that the arrangement of the screen grid elements is different from each other. In the case of electron gun 26 ', the screen grid electrode system 38' comprises a first metal part G 2 a 'and a second metal part G 2 b' arranged at a certain distance therefrom. The first part G 2 a 'is a substantially flat plate having a thickness of about 0.38 mm (15 mils) with three circular apertures 60 in the form of through holes arranged in a row. The three apertures 60 each have a diameter of 0.635mm (25 mils) and are each aligned with an aperture in the control grid 36 (G 1). The second part G 2b 'has a thickness of about 0.30 mm (12 mils) and three incorporated horizontally disposed slots 62. The slots 62 have the same dimensions as the slots 52 described above; however, with the gun 26 ', the slots 62 face the first part G 2 a' of the screen grid electrode system 38 '. The circular apertures 64 are also 0.635 mm (25 mils) in diameter and are aligned with the apertures 60 in the first part G 2 a '.

As described above, a dynamic signal voltage is applied to the second part G 2 b '. If the first part G 2a 'relatively thin, some brightness modulation in the order of 20 to 30% occurs. However, it can be compensated for by applying a countermodulation to the cathode 34, or, it can be limited by increasing the thickness of the first part G 2 a 'to shield the control grid 36 to a minimum.

It is also within the scope of the invention to slit both the first and second parts of the screen grid electrode system 38. Such a structure is shown in FIG. The slots are machined into the opposite surfaces of the screen grid parts G2a and G2b, and the slits shown in dashed lines are arranged perpendicularly and horizontally at right angles to each other.

Claims (7)

claims: A slot mask electron gun for use in a cathode ray tube, the electrode gun including a plurality of cathodes, a control grid, a screen grid electrode system, and at least two main focusing lens electrodes, in the order and spaced apart, characterized in that the screen grid electrode system comprises two spaced metal parts (masks G2a, G2b, G2a ', G2b'), at least one of the parts (G 2 a, G 2 b ') having a plurality of elongated rectangular slots (52; 62) machined in one of its faces , and wherein the slots have a depth which is smaller than the thickness of the part and opposed to the other part (G 2 b; G 2a '), and a plurality of circular apertures (54, 64) communicating with the slots and go through the part. 2. An electron gun according to claim 1, characterized in that the parts of the screen grid electrode system (38) remote from each other, a first part (G 2a), which is located next to the control grid (36), and a second part (G 2 b), the between the first part and the main focusing lens electrodes (42, 40), the first part being provided with the oblong rectangular slots (52) facing the second part. 3. electron gun (26) according to claim 2, characterized in that the first part (G 2 a) has a thickness which is greater than that of the second part (G 2 b). 4. electron gun (26 ') according to claim 1, characterized in that the arranged at a certain distance from each other parts of the screen grid electrode system (38') a first part (G 2 a ') next to the control grid (36) and a second part (Eq b ') between the first part and the main focusing lens electrodes (40, 42), the second part having the elongated rectangular slots (62) facing the first part. 5. electron gun (26, 26 ') according to claim 3 or 4, characterized in that the rectangular slots (52, 62) were extended in the direction of escape of the electron gun. 6. electron gun (26,26 ') according to claim 3 or 4, characterized in that on the second screen grille part (G 2 b, G 2 b') a modulation voltage is applied. 7. An electron gun according to claim 1, characterized in that the metal parts (G 2 a, G 2 b) of the screen grid electrode system (38) a plurality of elongated rectangular slots, which are incorporated in one of the surfaces thereof, wherein the slots have a depth , which are smaller than the thickness of the metal parts and opposed to the other metal parts, and a plurality of circular apertures (54) incorporated in each of the metal parts, communicating with the slots and passing through the metal parts, the slots of a metal part are arranged at right angles to the slots in the other metal part. For this 3 pages drawings.