DE2921127A1 - Cathode ray tubes - with arc limiting coating in the envelope comprising an insulating oxide, graphite and a silicate binder - Google Patents

Abstract

CRT comprises an envelope with a conical section and a neck, with an anode button sealed into the cone. A mounting assembly carrying damper elements is sealed into the neck. The interior of the envelope is coated with an adherent layer of a compsn. to limit the formation of arcs, comprising particles of an insulating oxide (I), particles of graphite (II) and a silicate binder (III), with a wt. ratio of (I):(II) of 5:1 to 16:1, the resistance of the coating being 5 kg-ohms to 1000 kg-ohms, measured between the anode button and the damper elements. The coating replaces prior art conductive coatings used as a discharge path for secondary electrons emitted from the perforated screen as a result of impact of the prim. electrons on the screen. The new coatings limit arcing over the conductive coating, which can have the effect of damaging transistor circuits by surge currents resulting from the arcing.

Description

State of the art:

It is known that cathode ray tubes on the inner surface of their Glass bulbs need a conductive coating for secondary electrons that pass through Primary electrons in the area of the perforated screen and the slit or shadow mask triggered, serves as a discharge path. Usually this was the discharge path formed by a so-called "soft" aquadag coating, the one on the inner surface of the glass bulb between the screen, the high-voltage bushing and the electron gun system attached to the neck part.

Due to the progressive use of semiconductors in television receiver circuits A new problem arose because of the sensitivity of these components to the by Flashovers in the picture tube induced currents. About the conductive covering and the high voltage supply could wreak havoc on the flashovers Effect circuit.

That is why it became necessary to use the so-called "soft" Aquad surface to be replaced by a resistor coating, which prevented these high current values, which occurred during the undesired flashovers within the picture tube.

Accordingly, a rollover-preventing surface was developed and introduced, which has a glass frit and conductive oxides such as cadmium and tin oxides. This Coating provides a relatively high resistance value and thus limits the currents through Rollover. But now both the desired conduction path for the derivation of secondary electrons to have as well a current-limiting path for dissipation at the same time limiting the currents of flashovers, the need was recognized Provide three different linings on the inner surface of the glass bulb. A senior The coating was applied in the area between the screen and the high-voltage bushing. A kind of "bus-bar" type covering with low resistance as a tape or strip was applied in the neck zone to make contact with the resilient Support members provided on the last electrode system. A frit or a flap The limiting surface made contact with the two surfaces mentioned. So had to Currents through flashovers, which mostly take place in the electron system, the coating with high resistance on their way to the button for the high voltage connection and the Overcome connected electronic circuit with semiconductor components and the current peaks were reduced considerably.

This known solution with three different coverings is proven and still widely used today. However, it has the disadvantage of being very expensive to produce to be because of a large amount of equipment as well as manpower, time and material are necessary.

In order to reduce costs, another solution was sought, whereby a resistance coating consisted of iron oxide, graphite and silicate binders. This Iron oxide coating contained oxide to graphite particles in a ratio of about 2: 1 to 6: 1 and a resistance of about 508 to 25,400 ohms per centimeter.

However, so far only the resistance value of a covering has been used for the Determination of the current limiting properties and the impedance characteristics are observed in terms of capacitance and inductance have been overlooked. As a consequence of this relatively large amounts of conductive particles were used in coatings to produce such a To achieve resistance value that was in a range that the usual high-voltage conditions -nation of the cathode ray tube allowed and then undesirably high currents prevented as a result of rollovers.

However, it has now been shown, disadvantageously, that coverings that are relatively containing large amounts of graphite, a greater tendency to decreased separation of the conductive graphite particles and an increased tendency to form loose particles made of electrically conductive material. The latter are effective when the tubes are in operation mostly destructive. In other words, it causes the proportion of graphite particles to increase a coating that limits rollovers, an undesirable increase in the probability of loose particles of the conductive material and an undesirable increase in impedance because of the relatively poorer separation of the conductive graphite particles from one another.

Task: The invention was therefore based on the task of creating a cathode ray tube to improve their inner lining or their inner lining, that defects are known Executions are avoided, with rollover or the currents triggered by them should be limited by a resistance layer, which adheres well to the glass and does not tend to loose particles. At the same time should this coating has as few as possible, evenly distributed, conductive particles.

This task is for the specified preamble of the main claim solved according to the license plate.

Further details and refinements are to be found in the remaining claims and to be taken from the description.

The invention and its advantages: The covering according to the invention contains Non-conductor oxide particles, graphite particles and a silicate binder, the Non-conductor oxide particles to the graphite particles in a weight ratio between be around 5: 1 and 16: 1. The proportion of graphite particles used is as low as possible with a well-distributed mixture. The covering adheres well to the inner glass surface of the glass bulb and does not tend to loose particles due to abrasion in the further Completion of the tube. The covering has a minimal amount of conductive components.

In addition, the materials for the covering are relatively easily available At reasonable prices and after a suitable mix, uncomplicated according to normal Apply manufacturing process in the picture tubes.

Drawing: A preferred embodiment is based on the drawing described below. This shows in one figure a partially longitudinally sectioned Side view of a picture tube.

Description: / shows how the only figure is made up of the glass bulb 3 a cathode ray tube from the front glass panel or screen part 5, which by means of a frit is connected to a funnel part 7. The latter follows a neck part 9, which is terminated with a tubular base. In the neck part 9 is the electron gun system 13 is mounted and has on its front periphery attached, resilient support members 15 which are supported on a covering 27, the from the neck zone to a high-voltage bushing 11 on the inner surface of the Glass bulb 3 is applied.

Usually there is a layer on the inner surface of the screen part 5 of luminescent phosphor material 17 with a light reflective applied thereon Metal coating 19. A pinhole or slit mask 21 is attached to its frame, which is at several fastening points 23 on the side walls of the screen part 5 supports.

A covering 25 of conductive material such as "Aquadag" is on the inner surface of the glass bulb 3 between the hole or Slit mask 21 and the high-voltage bushing. The lining 27 closes slightly overlapping at the high-voltage bushing on this covering 25.

During the manufacture of the cathode ray tube, the impact limit is limited Coating 27 applied from a slurry in the area of the specified above Tubular piston 3.

This is preferably done by removing the funnel and neck part 7 and 9 is rotated and at the same time spread the slurry with a brush will. However, it should be mentioned that the cover 27 is also in the form of a narrow Tape between the high-voltage bushing 11 and the support zone of the support members 15 can be formed in the neck part 9. Likewise, there is an expansion from the support members 15 up to the zone of the mask 21 is possible.

Thereafter, the electrically conductive covering 25 is sprayed on or with a sponge or brush applied in the funnel part 7, the overlap with the deck 27 is staggered. The finished front glass or screen part 5 is now under Intermediate layer of a bead made of fritted material placed on the funnel part 7 and at exact positioning and alignment at around 4500 C and the pads fused 25 and 27 carefully dried. If now the electron gun system 13 in the Neck part 9 is introduced, the support members 15 come on the edge of the covering 27 to the condition If this covering 27 does not have the necessary hardness and adhesion has, something can easily be scraped off from the coating 27 here. Afterward the tube is completed in a known manner by baking, suction and sealing.

The covering 27 is made so that minimal amounts of the conductive Graphite material and increased amounts of the dielectric oxide material are used will. More precisely, the weight ratio of the dielectric oxide particles to the graphite particles is between about 5: 1 and .6: 1. So is the topping like Required to be resistant to abrasion and there are no loose particles in the tube generated that could cause flashovers with a destructive effect.

Going into more detail, the following preferred approach emerged: About 50 to 65 parts by weight of the dielectric oxide particles, about 4 to 10 parts by weight the graphite particles and about 25 to 35 parts by weight of the silicate solids were used. Small amounts of graphite particles and silicate solids were selected in order to reduce the tendency to flash over due to loose, conductive particles. In addition, undesirable life problems have been observed when excessive of silicate is present.

It was finally discovered that the most commonly used method the resistance measurement as a criterion for determining the ability to limit rollover leaves a lot to be desired. A more accurate determination provides a measurement both the resistance as well as the impedance of the coating. More precisely, there is the measurement resistance and capacitance make a meaningful statement about the ability of the Covering to limit flashovers or the resulting current peaks.

As a result, it has been found that a minimal amount of the conductive Material, in the example graphite, which is well solved in the SusDension, where each conductive particles isolated from - / ut is adjacent conductive particles, especially gives favorable results. A weight ratio has turned out to be as indicated proved to be optimal. This led to measured resistance values between about 5 k ohms and 1000 k ohms, preferably 50 k ohms to 1000 k ohms and a resistance value between about 3 and 300 pF over a straight distance of about 10 cm in a straight line and between the high-voltage bushing 11 and one of the support members 15.

In a tried and tested version, which is not limiting for the claim is to be understood, the approach for the rollover was limiting Topping 27 made of 40 g of the "Fisher I 116" iron oxide, available from Fisher Scientific, N.Y., mixed with 46 ml of "PS-Kasil", a 35 weight percent silica Potash silicate manufactured by GTE Sylvania Inc., Towanda, Pa. and made 30 ml of water.

This was processed in a ball mill for 24 hours, whereby a quarter liter Burundum jar with a 13 mm Burundum cylinder was used. 6 drops of ammonia and 27 ml of "Acheson No. 31 Aquadag" were then prepared from the Acheson Co. of Part Huron, Michigan and mixed in for 2 hours in processed by the ball mill. This mixture was poured into a clean bottle and preferably applied with a paintbrush or a brush in one about 10 cm wide stripes in the mentioned zone on the inner glass surface of the piston j.

The coating 27 produced in this way had a resistance value as well as a capacitance value within the specified values. It was found that this covering 27 is very suitable is for conditioning with high voltage, with a considerably high voltage serves to burn out any loose particles that may be present.

Alternatively, iron oxide or dielectric oxide particles can be substituted are replaced by equivalent non-conductor Oxide particles. Come for it in question: iron oxide, oxide-oxide-iron, chromium oxide, aluminum oxide, titanium oxide, nickel oxide and nickel sesqui oxide.

Other materials can be used as binders instead of potassium silicate can be used with very good results such as sodium silicate and lithinum silicate, individually or in combination with each other or with potassium silicate and provide a equally good approach.

Cathode ray tube with an inner coating that limits flashovers.

the topping.

Summary: A cathode ray tube has a glass bulb, on the inner surface of which a coating limiting rollover is applied and of dielectric oxide particles, graphite particles and a silicate binder consists, wherein the dielectric oxide particles and the graphite particles in a weight ratio from about 5: 1 to 16: 1.

The invention relates to a cathode ray tube according to the preamble of the first claim.

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Claims (14)

Claims: 1. A cathode ray tube consists of a glass bulb, whose screen part, funnel part and neck part are fused together, with A high-voltage bushing is used in the funnel part and an electron gun system in the neck part with contact-making, axially directed, resilient ones attached to the last electrode Support members used and a perforated or slit mask means in the screen part a frame is attached, this cathode ray tube has an inner lining on the inner glass surface of the neck and funnel part to prevent or limit of rollover currents and this coating contains dielectric oxide particles, graphite particles and silicate binder and is characterized by the combination of the following features A. The dielectric oxides and the graphite particles have a weight ratio from about 5: 1 to 16: 1; B. The surface has a resistance between about 5 kDhm and 1000 k ohms, measured from the vicinity of the high-voltage bushing to the resilient support members. 2. A cathode ray tube according to claim 1, characterized in that that the dielectric oxide particles are selected from a group consisting essentially of from iron oxide, Eisenoxydul, Oxyd-Oxydul-Eisen (ferrous-ferric oxide) Chromo-oxide, aluminum oxide, titanium oxide and nickel-sesqui-oxide consists. 3. A cathode ray tube according to claim 1, characterized in that that the dielectric oxide particles range from about 50 to 65 parts by weight, the graphite particles in the range of about 4 to 10 parts by weight and the silicate binder Have silicate solids in the range of about 25 to 35 parts by weight. 4. A cathode ray tube according to claim 1, characterized in that that the rollover-limiting coating has a capacity in the range from about 3 to 300 pF, measured from the area around the high-voltage bushing to the resilient ones Support members. 5. A cathode ray tube according to claim 1, characterized in that that the rollover-limiting coating has a resistance in the range of about 50 k Ohms to 1000 k ohms. 6. A cathode ray tube according to claim 1, characterized in that that the dielectric oxide particles are in the form of iron oxide particles. 7. A cathode ray tube according to claim 1, characterized in that that the dielectric oxide particles are in the form of iron oxide particles. 8. A cathode ray tube according to claim 1, characterized in that that the dielectric oxide particles are in the form of oxide-oxydul-iron (ferrous-ferric-oxide) particles are. 9. A cathode ray tube according to claim 1, characterized in that that the dielectric oxide particles are in the form of chromium oxide particles. 10. A cathode ray tube according to claim 1, characterized in that that the dielectric oxide particles are in the form of alumina pieces. 11. A cathode ray tube according to claim 1, characterized in that that the dielectric oxide particles are in the form of titanium oxide particles. 12. A cathode ray tube according to claim 1, characterized in that that the dielectric oxide particles are in the form of nickel oxide particles. 13. A cathode ray tube according to claim 1, characterized in that that the dielectric oxide particles are in the form of nickel sesqui oxide particles. 14. A cathode, beam tube according to claim 1, characterized in, that the silicate binder contains silicates from the group of elements which includes sodium potash and lithinum.