NL9000117A - CATHED BEAM TUBE. - Google Patents

Description

The invention relates to a cathode ray tube provided with an envelope, comprising on one side a phosphor screen and on the other side a neck part, with an electron gun positioned in the neck part, which contains a beam-forming part and a focusing structure, which focusing structure has a hollow at the ends. tube of electrically insulating material, having an inner surface on which a layer of a material having a high electrical resistance is applied, and a getter device arranged in the enclosure.

Such a cathode ray tube can be used in black and white, in color and projection television, in devices for displaying numbers and letters (Data Graphics Display) and in other devices in which a cathode ray tube is used.

Although theoretically good focusing can be obtained with the aid of a layer of a material with a high electrical resistance, which layer has, for example, a helical structure and a voltage difference is applied over the ends of which layer, a focusing difference is not always found in practice. meet expectations.

It is an object of the invention, inter alia, to provide a cathode ray tube provided with an electron gun with a focusing structure of the above-described type, which provides good focusing.

According to the invention, a cathode ray tube of the type mentioned in the preamble has the feature for this purpose that the layer on the inner surface of the hollow tube is shielded from the getter device.

The invention is based on the following insight.

Generally, the envelope is evacuated during the manufacture of a cathode ray tube. The cathode ray tube is heated to a temperature of, for example, about 400 ° C, in order to promote degassing of the parts of the cathode ray tube. In order to bind the released gases during the evacuation and also during the life of the cathode ray tube, it is usual to arrange a getter device in the cathode ray tube. This gettering device contains material capable of binding the released gases. In television tubes, for example, the material includes metallic barium. In order to obtain a sufficient gas bonding, getter material is generally placed in the casing and atomized in a manufacturing step (the getting), so that a layer of finely divided getter material is formed, for example on the inner wall of the casing. The invention is based on the insight that the required high electrical resistance of the layer (of the order of 10, WQ, for example) is undesirably lowered during this atomization, because electrically conductive getter material can end up on the layer of resistance material. If the high-resistance resistor layer has a helical structure, the generated focusing field can be disturbed because deposited getter material causes a short circuit between individual windings.

In the cathode ray tube according to the invention, the inner surface of the hollow tube is shielded from the gettering device, which means that during the coating the layer of a material with a high electrical resistance of the focusing structure is shielded from the deposition of atomized gettering material. This shielding is realized by a specific mutual positioning of the hollow tube and getter device and / or by the use of shielding means.

In conventional electron guns with metal lens focusing lenses, it does not matter whether or not getter material gets on the focusing lens parts.

In a cathode ray tube in which the getter device is disposed between the end of the hollow tube and the phosphor screen, for example on the anode contact, according to a preferred form of the invention, the inner surface of the hollow tube is effectively shielded from the getter device by the end facing the phosphor screen of the hollow tube, an auxiliary tube open at the ends is arranged, the axis of which is almost in line with the axis of the hollow tube. It has been found in practice that the atomized getter material mainly deposits on the end of the hollow tube facing the phosphor screen. By now providing the hollow tube with an auxiliary tube open at the ends, the getter material atomized towards the hollow tube end largely or completely deposits on the auxiliary tube and not on the high-ohmic resistance layer.

Even when the getter device is not placed between the end of the hollow tube and the phosphor screen, but for example around the hollow tube, the shielding of the resist layer against atomized getter material by the auxiliary tube is more efficient. The auxiliary tube is, for example, cylindrical or conical.

In a preferred form of a cathode ray tube according to the invention, the smallest inner diameter of the auxiliary tube is smaller than the inner diameter of the hollow tube. When the inner diameter of the auxiliary tube is smaller than the inner diameter of the hollow tube, the auxiliary tube also functions as a diaphragm. Due to the diaphragm effect, the shielding of the high ohmic layer on the inner surface of the hollow tube of the gettering device is efficient.

Good shielding is also obtained when a diaphragm is attached to the hollow tube end.

A further preferred form of a cathode ray tube according to the invention is characterized in that the auxiliary tube is made of electrically insulating material.

Generally, during the operation of a cathode ray tube, an generated electron beam is deflected over the phosphor screen by means of a deflection unit. The deflection field generated by the deflection unit may extend close to or even into the focusing structure. The deflection field is not impaired by manufacturing the auxiliary tube from electrically insulating material. It is practical when the auxiliary tube is part of the hollow tube. As a result, fewer separate parts are required in the cathode ray tube.

An alternative embodiment of a cathode ray tube according to the invention, in which the deflection field to be generated is practically not adversely affected, is characterized in that the auxiliary tube is made of electrically conductive material and is provided with at least one slit which is substantially parallel to the axis of the hollow tube. The gaps in the auxiliary tube prevent eddy currents from forming in the auxiliary tube that could disturb the deflection field.

Preferably, the getter device is attached to said end of the hollow tube at a position between said end and the phosphor screen, so that the getter device is integrated with the focusing structure and fewer separate parts are required in the cathode ray tube.

A further preferred form of a cathode ray tube according to the invention is characterized in that the getter device is located in the neck section between the hollow tube and the inner surface of the neck section. As a result, the atomized getter material largely or completely ends up on the outer surface of the hollow tube and on the inner surface of the neck section, so that the chance that the electrical resistance of the layer on the inner surface of the hollow tube is adversely affected is minimal.

In order to prevent the getter material from getting onto the high-ohmic resistance layer via the end of the hollow tube remote from the phosphor screen during atomization of the getter, in a preferred form of a cathode-ray tube according to the invention, between the end of the phosphor screen facing away from the hollow tube and the inner surface of the neck portion of the cathode ray tube is shielded. The atomized getter material will end up on the shield.

Some embodiments of a cathode ray tube according to the invention will be explained with reference to the drawing, in which:

Figure 1 schematically shows a longitudinal section of a cathode ray tube according to the invention, and

Figures 2 to 6 each schematically show a longitudinal section of an alternative embodiment of a cathode ray tube according to the invention.

In Figure 1, a cathode ray tube 1 is shown containing a phosphor screen 40 mounted on a display window 41 and an electron gun 3 mounted in a neck portion 2. A G1 (grid) electrode structure is provided with a typical opening behind which is a cathode 4 with an electron-emitting surface arranged with a filament 5 adjoining it. A G2 electrode structure, in this case in the form of a metal plate 6 with a central opening, is placed more forward adjacent to the G1 electrode structure. Even more to the front is a G3 electrode structure in the form of a metal plate. To form an assembly, the electrode structures G1, G2 and G3, which form the beam-forming part - in this case the triode part - of the gun are attached to insulating mounting rods (rods) via pins (or brackets), one of which is shown 8 in Figure 1. In this case, two mounting bars are used. However, the invention is not limited to this. For example, four or three mounting bars may be used in an alternative and customary manner. A focusing structure 10 comprises a hollow tube 12 of an electrically insulating material, for example glass or ceramic, which hollow tube 12 is covered on its inner surface with a layer 14 of a material with a high electrical resistance. The tube 12 is fixed at its end 13 to a flange 17 of a metal plate 16, which flange surrounds an opening 18 in the plate 16, via which metal plate 16 is attached to the mounting rods to which the beam-forming part of the gun is also attached. is attached. At its end 15, the tube 12 is attached to the mounting bars in an analogous manner, by means of a metal plate 31. To obtain good focusing, a voltage difference is applied across the ends of the layer by the metal plates 16 and 31 to external voltage sources (not shown in Figure 1). The layer 14 can be in the form of one or more rings, or it can for example have a spiral shape or a combination of one or more rings with a spiral. The electron gun 3 in this embodiment is positioned in the neck portion 2 by means of a centering unit with resilient elements 32. The resilient elements 32 also provide an electrical connection between plate 31 and an electrically conductive layer 33 applied to the inside of the envelope of the cathode ray tube 1.

An anode contact 42 is provided in the housing for supplying a desired potential to the conductive layer 33. A getter device 43 is provided on the anode contact 42.

The getter device 43 contains getter material 44 which is capable of binding released gases and thus ensures the vacuum in the enclosure. To obtain good gas bonding, the getter material 44 is atomized in a grease manufacturing step to form a layer of finely divided getter material. Attached to the end 15 of the hollow tube 12 facing the phosphor screen 40 is an auxiliary tube 45 open at the ends, the shaft 46 of which is substantially in line with the shaft 47 of the hollow tube 12. Since getter material atomized in the direction of the hollow tube 12 largely or entirely deposits on the auxiliary tube 45, the inner surface of the hollow tube 12 where the resistive layer 14 is applied is shielded from the getter material. The electrical resistance of the resistive layer 14 and the focusing of the focusing structure 10 are practically or not at all affected by the atomized getter material by the provision of the auxiliary tube 45.

In Figure 2, an alternative embodiment of a cathode ray tube according to the invention is schematically shown in longitudinal section. Like reference numerals indicate like parts in Figures 1 and 2. In this embodiment, the getter device 43 is provided with a shielding shield 50. This shielding shield 50 is positioned between the getter material 43 and the hollow tube 12. Sputtered getter material precipitates onto the shield shield 50, and substantially no sputtered getter material spills onto the high-ohmic resistor layer 14. The resistance layer 14 is thus shielded from the getter device 43.

During the operation of the cathode ray tube, the generated electron beams are deflected over the phosphor screen 40 by means of a deflection unit (not shown in the figure). The deflection field generated by the deflection unit may extend close to or even into the hollow tube 12 of the focusing structure. The auxiliary tube 45 should hardly affect this deflection field, especially at higher frequencies.

If the auxiliary tube 45 is made of metal as shown in Figure 1, the deflection field is practically not adversely affected when the auxiliary tube 45 is provided with one or more slits 51. The slits 51 are substantially parallel to the axis 47 of the hollow tube 12. The number of gaps 51 to be provided in the auxiliary tube 45 depends on the adverse effect of the auxiliary tube 45 on the deflection field.

Preferably, the auxiliary tube 45 is made of an electrically insulating material, for example of glass. As a result, a generated deflection field is not adversely affected in a simple manner. In Figure 1, the inner diameter of the auxiliary tube 45 is equal to that of the hollow tube 12. Preferably, the inner diameter of the auxiliary tube 45 is smaller than that of the hollow tube 12, so that the resistive layer 14 is better shielded from the getter device.

In Figure 3, an alternative embodiment of a cathode ray tube according to the invention is schematically shown in longitudinal section. In this embodiment, the hollow tube 12 carries both the focusing structure 10 and the electrodes of the beam-forming member. The supply of electrical potentials to the electrodes of the beam-forming part and the focusing structure is effected, for example, by means of lead-through wires (not shown in Figure 3) through the hollow tube 12. The hollow tube 12 is suspended in the neck portion 2 from connecting pins 23 and with resilient elements 32. In this embodiment, the. auxiliary tube 45 an extended part of the hollow tube 12. The end of the auxiliary tube 45 is closed by a diaphragm 52 on which a part of the atomized getter material precipitates. The resistive layer 14 on the inner surface of the hollow tube 12 extends up to the auxiliary tube 45.

It has been found in practice that when the auxiliary tube 45 has an inner diameter equal to that of the hollow tube 12 and a length of 15 mm, substantially all of the atomized getter material precipitates on the inner surface of the auxiliary tube 45. In this case, the diaphragm 52 on which some of the atomized getter material deposits is even superfluous. In this way, the resistive layer 14 is unnecessarily shielded from the gettering device without unnecessarily increasing the number of parts of the cathode ray tube.

Figure 4 schematically shows a part of a cathode ray tube according to the invention, in which the hollow tube 12 carries both the focusing structure 10 and the auxiliary tube 45 and, moreover, the getter device 44. The getter device 44 is attached to the centering unit with resilient elements 32 by means of metal strips 48.

The getter device 44 in this embodiment is located 22 mm from the end of the hollow tube 12 in the direction of the phosphor screen 40. The hollow tube 12 has an inner diameter of 10 mm. The auxiliary tube 45 is 7 mm long and has an inner diameter of 6 mm. Since the auxiliary tube 45 has a smaller inner diameter than the hollow tube 12, the auxiliary tube 45 has a diaphragm effect. A length of 7 mm then appears to be sufficient to realize that practically no atomized getter material precipitates on the resistance layer 14. This results in an integrated unit that is easy to handle during the manufacture of the cathode-ray tube and in which, despite the compact construction in which the getter device 44 is positioned at a relatively short distance from the hollow tube 12, the resistance layer 14 is still sufficiently shielded from the getter device 44 .

Figure 5 shows an alternative embodiment of a cathode ray tube according to the invention. The getter device 9 in this case is located in the neck section 2 around the hollow tube 12. The getter device 9 contains getter material 19 which after spraying forms a layer 20 of finely divided getter material. This layer 20 of sputtered getter material is almost entirely on the outer surface of the hollow tube 12 and on the inner surface of the neck portion 2. Due to this construction, hardly any getter material ends up on the resistance layer 14. In this embodiment, the getter device 9 is annular and is attached to the centering unit by means of strips 52. However, the invention is not limited to this.

For example, the getter device 9 may be attached to the mounting bars (one of which is 8 shown) or carried by the hollow tube 12 or the neck portion 2.

An in this case annular shield 21 is arranged near the end 13 of the hollow tube 12, between the hollow tube 12 and the inner surface of the neck portion 2. Getter material which goes towards the cathode 4 during sputtering on the annular shield 21 rightly so. This prevents getter material from depositing on the high-resistance layer 14 via the end 13 of the hollow tube. The shield 21 can for instance be made of metal or insulating material.

In the embodiment of a cathode ray tube according to the invention as shown in Figure 6, the gettering device is formed by two annular troughs 9 and 9 'which can be attached directly or indirectly to the hollow tube 12, whereby a simple construction is obtained. Before the spraying process, getter material is contained in the gutters. After sputtering, the getter material is at least partially on the outer surface of the hollow tube 12 and on the inner surface of the neck portion 2.

A conical shield cap 22, the diameter of which in this case decreases towards the phosphor shield, is interposed between the hollow tube 12 and the inner surface of the neck portion 2, thereby preventing unwanted deposition of getter material on the high-ohmic resistance layer 14.

Since little or no getter material ends up on the focusing structure in a cathode ray tube according to the invention, a good focusing of the electron beams on the phosphor screen is obtained.

The invention has been described with reference to a cathode ray tube with one electron gun, but it will be clear to the skilled person that the invention is also applicable to color cathode ray tubes.

Claims (10)

1. Cathode ray tube provided with an envelope, comprising on one side a phosphor screen and on the other side a neck section, with an electron gun positioned in the neck section, which contains a beam-forming part and a focusing structure, which focusing structure is a hollow tube of electrically insulating open ends material, having an inner surface on which a layer of a material having a high electrical resistance is applied, and a getter device arranged in the envelope, characterized in that the layer on the inner surface of the hollow tube is shielded from the getter device. Cathode-ray tube according to claim 1, characterized in that an auxiliary tube, open at the ends, of which the axis is substantially aligned with the axis of the hollow tube, is arranged on the end of the hollow tube facing the phosphor screen. Cathode ray tube according to claim 2, characterized in that the inner diameter of the auxiliary tube is smaller than the inner diameter of the hollow tube. Cathode ray tube according to claim 2 or 3, characterized in that the auxiliary tube is made of electrically insulating material. Cathode ray tube according to claim 4, characterized in that the auxiliary tube is part of the hollow tube. Cathode ray tube according to claim 2 or 3, characterized in that the auxiliary tube is made of electrically conductive material and is provided with at least one slit which is substantially parallel to the axis of the hollow tube. Cathode ray tube according to claim 2, 3, 4, 5 or 6, characterized in that the getter device is mounted on said end of the hollow tube at a position between said end and the phosphor screen. Cathode ray tube according to any one of claims 1 to 6, characterized in that the getter device is placed in the neck portion of the cathode ray tube between the hollow tube and the inner surface of the neck portion. Cathode ray tube according to any one of the preceding claims, characterized in that the getter device comprises an annular trough. Cathode ray tube according to any one of the preceding claims, characterized in that a shield is placed between the end of the hollow tube remote from the phosphor screen and the inner surface of the neck portion of the cathode ray tube. V