DE2703093C2 - Color television tube - Google Patents

Description

45

The invention relates to a color television picture tube according to the preamble of claim 1.

Such a color television picture tube is known from GBPS 12 26 728. The electrical resistance layer serves to limit the harmful consequences of an electrical flashover that can occur between electrodes of the electrode system that are located a short distance from one another when the tube is in operation. Although favorable results can be achieved with such a resistive layer with regard to the protection of the electronic circuit of the television receiver, it has been found that the use of this layer is not entirely problem-free in other respects. that a switched-on television receiver can be a source of interference for a radio receiver arranged in its environment, which is tuned to a transmitter in the long or medium wavelength range. Much of this interference comes from the video signal. When the picture tube is in operation, the screen is scanned with electron beams modulated in accordance with the video signal. Some of these rays reach the screen via the openings in the color selection electrode, while the non-transmitted part of the rays falls on the color selection electrode itself. The electrical potential of the color selection electrode and the screen fluctuates according to the amplitude of the video signal. These fluctuations are emitted from the screen as interference radiation /

In US-PS 39 59 686 a color picture tube is described in which the resistance layer is not up extends into the neck of the tube, but between two each with a high voltage contact connected low-resistance conductor layers. This complicated construction is intended to the so-called »hardening of the electron beam generator by means of protrusions« during the manufacture of the tube to facilitate.

The invention is based on the object of taking measures to reduce the above-mentioned interference radiation in a color television picture tube of the type mentioned at the beginning.

According to the invention, the features specified in the characterizing part of claim 1 are used to solve this problem in a color television picture tube of the type mentioned at the outset.

The invention is based on the knowledge resulting from investigations that the interference radiation emitted by the tube is lower if the electrical connection path between the color selection electrode and the resistance layer forms a lower electrical resistance.This resistance is essentially through in tubes with an inner resistance layer determines the contact resistance between the contact spring and the resistance layer. This contact resistance is attributable to the fact that the resistance layer consists of a mixture of electrically good and electrically poorly conductive particles. The contact resistance is higher, the lower the number of electrically conductive particles of the resistance layer that is in contact with the contact spring. By using the invention, the effective contact surface between the resistance layer and the contact spring is increased, thereby reducing the contact resistance. In a practical example in which the resistance layer had a resistance of approximately 1000 Ω per square, a contact resistance of approximately 5000 Ω was measured without using the invention. After applying a low-resistance contact surface with a size of approximately 5 cm ² and a resistance of approximately 25 Ω per square to the resistance layer, it turned out that the contact resistance was reduced by approximately a factor of 100. This resulted in a reduction in the level of interference radiation by about 1OdB. The expression "low resistance" means that the electrical conductivity of the contact surface is as large as possible and preferably at least a factor of 20 greater than that of the resistance layer. Any tolerances with regard to the position of a contact spring are neutralized by giving the low-resistance contact surface an area of at least 5 cm ² . A contact surface in the form of a strip of low-resistance material on the resistance layer has proven to be particularly favorable. Such a strip has the advantage, due to its large surface area, that a good electrical coupling between the color selection electrode and the

Screen on the one hand and the condenser on the other hand is obtained by the inner coating of the Tube (the resistance layer) and the usual one connected to the chassis of the television receiver attached to the outside of the tube, low-resistance Upper pull is formed If more than one contact spring is used, the contact surfaces belonging to these springs form a whole with the above Stripes. The strip and the contact surfaces can consist of the same low-resistance material, so that they can be attached to the tube wall in a single processing step.

The invention is explained in more detail below, for example with reference to a drawing

F i g. 1 a color television picture tube in section,

F i g. 2 the cone provided with an inner resistance layer of the in FIG. 1 shown tube and

3 shows a possible attachment of a gas binding device in a picture tube according to FIG. 1.

The in F i g. 1 tube shown in a horizontal section contains a Giasumhüiiung, which consists of a front glass 1, a cone 2 and a neck 3 b \ - 3teht In dem Neck 3 is the electrode system 4 with three electron guns for generating three electron beams 5, 6 and 7. The electron beams are generated in one plane (here the plane of the drawing) and are directed to a screen 8 which is attached to the inside of the front glass 1 and which is made up of a plurality consists of a fluorescent strip covered with an aluminum layer that lights up in red, green and blue, their longitudinal direction to the plane through the electron gun (here the plane of the drawing) is perpendicular On its way to the screen 8 the electron beams 5, 6 and 7 by means of a number deflection coil S arranged coaxially around the tube axis is deflected over the screen S and pass while a color selection electrode 10, which consists of a metal plate with elongated openings 11, whose The longitudinal direction to the fluorescent strips of the screen 8 is parallel

The three electron beams 5, 6 and 7 pass through the openings 11 at a small angle to one another and consequently only hit fluorescent strips of a certain color. The tube also contains a inner resistance layer 12 and a highly conductive layer 13 applied to the outside of the cone 2. The resistance layer 12 has a thickness of about ΙΟμπι and consists of 1 part by weight of graphite powder, 6 to 10 parts by weight of iron oxide powder (FejOs) and 1.5 to 3 parts by weight of an inorganic binder such as potassium or sodium silicate. The resistive layer 12 is connected to a high-voltage contact 14 mounted in the tube wall. the Color selection electrode 10 is connected to screen 8 by means of a number of contact springs 15. A metallic shielding cone 16 is on the one hand with the color selection electrode 10 and on the other hand by means of two Contact springs 17 are connected to the resistance layer 12. When the tube is in operation, the layer 12 is at an operating potential of approximately 25 kV and the layer μ 13 to earth potential, because this is connected to the chassis of the receiver. Layers 12 and 13 form with the interposed glass of the cone 2 as a dielectric a capacitor, which acts as a smoothing capacitor is used for high voltage. This capacitor discharges when in the electrode system 4 electrical flashover between z. B. one electrode 18 and one at a short distance from this electrode lying electrode 19 occurs The current surge occurring during this discharge is in its size through the resistance layer 12, namely essentially through the transition from the neck to the cone and in the neck extending portion thereof, limited to that formed by the resistive layer Resistance is under dynamic conditions, i.e. during the electrical flashover mentioned above, generally lower than under static conditions. Under the term "static conditions" is Here the resistance is to be understood as the quotient of a voltage difference applied across the resistance layer of a few tens of volts and the consequent current flowing through the resistance layer For the composition of the layer given above, the dynamic resistance is about 500 Ω and the static resistance about 2000 Ω.

The use of a resistive layer reduces the filtering effect of the tube with regard to the interference radiation emitted by it. In this context it emerges that the contact resistance between the contact springs 17 and the resistance layer 12 is of particular importance, in the sense that the lower this contact resistance, the lower the amount of interfering radiation. In order to achieve a low contact resistance, a low-resistance contact surface in the form of a strip 20 is attached to the resistance layer 12 at the point where the contact springs 17 press against the tube wall. This strip 20 consists of a low-resistance material with a composition of 60 to 90 parts by weight of graphite and 10 to 40 parts by weight of an inorganic binder such as potassium or sodium silicate. Such a material can be applied in the form of an aqueous suspension with a brush. Instead of this material, other highly conductive materials, such as. B. aluminum can be used. The strip 20 has a triangle of about 5 cm and forms, as in FIG. 2 is shown, a closed ring on the inner surface of the cone z. With such a ring, due to its large contact surface, a good electrical coupling is also obtained between the color selection electrode 10 and the screen 8 on the one hand and the capacitor formed by the resistance layer 12 and the outer layer 13 on the other hand.

As is known, after evacuating the tube, a layer of a gas-binding material, e.g. B. barium, Strontium, calcium or magnesium, deposited on the tube wall to be retained in the tube To bind residual gases. In a common picture tube is the holder from which this gas-binding material is made dtich heating is triggered, either immediately or connected to the electrode system by means of a metal strip. With this common fastening method however, some of the gas-binding metal would be on the resistive layer 12 in place of the Neck and at the neck-cone transition are knocked down, whereby the resistance layer short-circuited would. In the event of an electrical flashover, sliding sparks can also occur along the fastening strip of the holder. An example of a possible mounting of the getter holder in which these problems avoided is shown in FIG. 3 shown. The getter holder 30 is located therein with the aid of a fastening strip 31 attached to the high-voltage terminal 14.

In this way it is achieved that the gas-binding material does not get on the neck and the neck-cone

Transition, but on the large part of the cone 2 is deposited. By shorting the Resistance layer at this point, the aforementioned filter effect of the tube is improved, while the dynamic resistance of the layer 12 during a 5th electrical flashover is hardly affected.

For tubes without a flat metal shielding cone or for tubes with an outer metal shielding cone, the contact springs 17 are z. B. directly attached to the frame of the color selection electrode 10, and io the low-resistance strip 20 is closer to the screen than it is in FIG. 1 is shown

1 sheet of drawings

55

Claims (5)

Patent claims: 1. Color television picture tube, consisting of a neck, a cone and a front glass, with a Electrode system in the neck for generating at least two electron beams, one on the Front glass arranged screen with a multitude of areas that light up in different colors, one that extends over almost the entire interior of the cone. wall up into the neck extending electrical resistance layer and a color selection electrode, which has a multitude of openings, over which each electron beam is assigned a certain color to the illuminated areas and which lies at a defined distance in front of the screen in the tube and electrically with the resistance layer via at least one metal contact spring that touches the inner wall of the cone is connected, characterized in that the resistance layer (12) at the point where the contact spring (17) touches the inner wall of the cone, with a highly conductive layer as a contact surface for the contact spring is covered 2. Color television picture tube according to claim 1, characterized in that the contact area has a size of at least 5 cm ² 3. color television picture tube according to claim 1 or 2, characterized in that the contact surface a strip (20) made of low-resistance material. 4. color television picture tube ncrh claim 3, characterized characterized in that the strip (5! 0) forms a closed ring. 5. color television picture tube according to claim 3 or 4, in which the color selection elekifodc at least two contact springs are connected to the resistance layer, characterized in that the contact springs (17) with the resistance layer (12) over a strip (20) made of low-resistance material and attached to the resistance layer are connected.