DE2542545A1 - Flashover suppressing device for CRT - has low resistance conductive coating on inner wall of CRT funnel coupled to HV terminal - Google Patents

Abstract

The flashover suppressing device is intended for cathode ray tube with conductive coating in the tube funnel from the screen to the neck portion, such conductive coating being provided on the outside of the tube funnel, but extending only to the mid portion of the funnel. The inner conductive coating has a lower resistance and is connected to the high voltage terminal. This coating reaches up to the end of the outer coating. From there a high resistance coating is provided on the inner wall and extends into the neck portion, having a skirt-like shape. Its surface is particle-free and resistant to wear. Inside the neck the coating forms an electric contact to the end electrode (45) or the anode of the electron gun, across a contact stirrup (49).

Description

Device for suppressing flashovers in cathode ray tubes The invention relates to a device for suppressing flashovers in Kaebdenstrahiröhren, the tube having a conductive coating in the funnel portion which is in proximity of the screen in the closure zone begins to extend up to or into the neck part extends and is at the shield potential, and wherein an outer conductive evidence is provided on the funnel part, which begins in the closure zone and goes up Extends over the central area of the funnel part and in a recess space läSt for the usual high-voltage bushing.

As the picture tube development shows, there is a general tendency to ever higher screen voltage, with the electron guns becoming more compact at the same time to be able to make the tube neck thinner. As a result, the Distances between the electrodes and supporting parts of the same are smaller while maintaining the same the characteristic construction data.

These conditions and the presence of possible contaminants increased the likelihood of flashovers in the tube.

The conductive inner coating mentioned at the beginning was found in most cathode ray tubes in the funnel part fed from the outside by means of a high-voltage bushing and was internal to the end electrode of the electron gun assembly as well as to the screen tied together. In the known constructions, there are therefore unfavorable conditions and there is a possibility of spark discharge between the electrode and the adjacent lower potential electrode in the gun assembly.

These flashovers are compounded by annoying elements such as sublime Precipitation, foreign bodies and / or small protrusions caused by the machining of the Electrode parts originate and protrude into the space between the electrodes, favored. Although great efforts are made during manufacture to all factors that the flashovers enable or facilitate to reduce, are in application of around 30 kV, even small flashovers are of great importance. rollover or dielectric breakdowns have always been undesirable accidents in cathode ray tubes and it has been observed that currents of up to 100 amperes and more occur they have a corresponding destructive intensity with regard to their effect. By doing Recently, semiconductor components have become more common in televisions and related or similar devices are used or almost exclusively those are used, Cathode ray tube flashover can cause catastrophic damage to the connected operating circuits and their semiconductor components. In addition, flashovers in cathode ray tubes damage the internal structures and the deposition of harmful precipitates in the area of the electron gun structure can cause.

Cleanliness, precision and care are constant requirements at every cathode ray tube manufacture to especially the conditions that cause flashovers promote or induce, to minimize. Nonetheless, play at this one Manufacturing human factors, manufacturing sublimations and tolerances at times together and let the absolutely undesirable situation arise.

The discreet application of high resistance coatings to the Inner surfaces of the funnel part have already been tried, such as that from US Pat. No. 2,829,292 can be seen solution. But it was observed that through the grid caused precipitation and other deposits within the tube tended to bypass the coating with high resistance, which was the purpose Improvement is wiped out again.

In addition, there were particles of the coating when the electron gun structure was inserted scraped off and left loosely within the glass envelope as an impurity. After this now efforts to suppress and minimize flashovers is of steadily increasing importance especially in the case of color picture tubes, a The main concern of the picture tube manufacturers is to develop an effective means of which allows to control the flashover as such in the picture tubes.

Therefore, the present invention was based on the object according to to reduce rollover problems known from the prior art} by constructive Measures should be found to reduce the tendency or possibility of arcing basically to reduce. Furthermore, it was demanded that this should be achieved effectively at an economically acceptable expense.

According to the invention, these tasks are carried out for the genus mentioned solved the character of the main claim, which has a combination of measures.

Further refinements and details of the invention are given below Refer to claims and are based on preferred exemplary embodiments, such as it contains the drawing.

In combination, three measures are provided according to the main claim: An inner liner made of low resistance material starting around the closure between the front part and the funnel part, which extends into the zone in the funnel, which represented the limit of the usual outer guide lining is adjacent to it a coating with high resistance is applied inside the funnel part up to the neck part, which makes the electrical connection between both the front covering made of material with low resistance as well as with the end electrode of the electron gun assembly finally produces at least one getter element with the discrete shape of a Diffusion direction transmitter attached to part of the electrode structure and oriented that the effusion of the getter material is not so directed that a Conductive path through the coating of high resistance material can arise. By this combination of measures will effectively suppress flashovers achieved and before the dreaded dielectric breakdown both the tube self protected as well as the circuits associated with it and their sensitive components. This is also achieved through the measures mentioned, so that there is an essentially common, i.e. uniform, electrical potential and between the low resistance coating and the end electrode of the Electron guns is obtained.

The drawing shows in Figure 1 a side view of a along a Cathode ray tube sectioned along the longitudinal axis, equipped according to FIG Invention; Figures 2 and 3 enlarged perspective view of the getter design As provided in Figure 1, Figures 4 and 5 are part of a sectional view similar to Figure 1 or a perspective view of another embodiment of the Getterausbildungl FIGS. 6 and 7 show a part of a sectional view similar to FIG 1 or a perspective illustration of a further embodiment of the getter construction; While the invention basically applies to conventional cathode ray tubes for black and white or Color television and also other related picture writing systems can be used, A color cathode ray tube has been used here for the description of the exemplary embodiments selected a shadow mask with many apertures as well as an "in-line" multi-beam electron generation arrangement owns.

Figure 1 leaves construction 11 of a multi-beam color cathode ray tube with the composite glass cladding consisting of neck part 13, Recognize funnel part 15 and the front plate 17. Front plate 17 and funnel part 15 are connected as usual by means of the closure 1-9 (seal). The patterned one Cathodoluminescent screen 21 is provided with color-emitting phosphor elements and applied to the inner surface of the faceplate 17, specifically as an arrangement more defined Prior art strips or dots. A shadow mask 23 is according to the pattern of the screen 21 provided with apertures of a discrete shape and by holding devices 25 oriented and fastened at a certain distance from the screen.

An exemplary and only partially detailed representation of the In-line multi-jet gun assembly 27 is arranged in the neck portion 13 of the tube so as to that the electron beams converge in the plane of the shadow mask 23 and then hit the patterned screen behind and selectively those there applied phosphor elements to light up.

It is common to have electrically conductive coatings on the outside and inside to apply on the glass of the funnel ax 15. These coatings have the Influence of the glass in between has a capacitive filter influence with the Circuits of the television receiver or the video writing device interacts. Of the outer coating 29 on the funnel part 15 can, for example, be a conductive material like "Aquadag" and extends from the closure 19 to the indicated level 31. The outer covering 29 leaves out the high-voltage connection 35, so it has none Connection with the high voltage. The lining 33 attached to the inside is made of a carbon-containing one material manufactured, such as "Aquadag" and is also to screen potential like the end electrode of the electron gun via the one in the funnel part 15 built-in high-voltage connection 35. This coating 33 is of low resistance. The inner lining 33 extends essentially from the closure 19 to the indicated Level 31, similar to the outer surface 29.

At the inner lining 33 closes after the level 31 to the Neck part 13 a coating 39 with high resistance, which is a tough adhesive connection with the inner surface of the glass. This topping 39 has a rock-like appearance Training and a front edge zone 41, which with-the rear edge zone 43 dec Covering 33 meets. At the rear end of the covering 39 in the neck part 13 is the End electrode 45 of the electron generating assembly 27 via resilient contact clips 49 allied with the covering 39, one of which is shown.

The coating 39 has, for example, a composition that is sintered glass contains as a base (a glass frit-based) as well as appropriate metal oxide inclusions. This mixture is fused to the glass wall of the neck part 13 by heat treatment, in order to achieve a largely abrasion-resistant and particle-free surface. A such resistive material has a resistance of 1c5 to 107 ohms each Square inches). This creates on the extensive surface of the covering 39 between the high voltage terminal 35 and the end electrode 45, a resistance path, the one Has resistance between 0.5 and 1.0 megohms. It has been shown that resistance values in this order of magnitude significantly limit the current and thus the occurrence of Prevent sparks.

In tubes that have this combination of coatings, exceeds the peak value of the spark current is rarely 0.5 to 1.0 amperes. In a typical electron gun setup 27, the anode or end electrode 45 has been supplied with a high voltage of 30 kV or more via the connection 35, while the adjacent focusing electrode 47 between 17 and 20% of the anode voltage. Because of this tension difference is a Current limitation and spark suppression in the area of the electrode gun assembly 27 very desirable.

Another very essential link in the combination for improvement the tendency to arcing is the use of getter agents with a specially shaped integrated diffusion directional transmitter. The latter is so arranged and equipped with an umbrella shape that the effusion of getter material in certain Way is directed so that no formation of conductive deposits on the Topping 39 is possible. Such a getter formation 51 is shown in FIGS 2 visible.

At the anode 45 of the electron gun assembly 27 is the ring-shaped Getter element 53 is fastened on the same axis and in parallel by means of the support elements 55. A diffusion direction transmitter 57 is formed in the shape of a ring and has an umbrella-like shape Bulge. Its inner edge is fastened on the inside on the periphery of the getter element 53. The getter material is activated by induction heating during the manufacture of the tubes. It has therefore proven advantageous not to use the diffusion direction generator 57 to manufacture from a seamless piece, but to provide at least one overlap 59. This avoids RF coupling and, as a result, excessive heating. In Figure 2 is the diffusion direction generator 57 partially cut away to the groove to make visible in the ring 53. The getter material 61 is embedded in it. the Getter formation 51 is attached to the electron gun assembly 27 so that the Electron beams can pass through the center unhindered. So it depends very much indicates that the entire getter formation 51 is positioned very precisely.

FIG. 1 and FIG. 3 show enlarged and more detailed a further getter formation 63, which by means of the retaining bracket 67 on the periphery of the frame 69 of the shadow mask 23 attached and adjusted in the manner shown is. It consists of an annular part 65 and is oriented with regard to its position so that that the effusion of the getter material is directed into the funnel part 15 and after the tube center is shielded by the diffusion direction generator 71.

The latter is designed so that no precipitation on the surface 39 with can reach high resistance. On one side is a cover 73 made of insulating material such as mica or glass, as it was known from US Pat. No. 3,420,593. These Cover 73 prevents direct precipitation on the near wall of the funnel part 15th

Figures 4 and 5 illustrate another getter design 73, as they are provided as further embodiments according to the invention. That Getter element 75 is again formed in an annular manner and here by a resilient one Support member 77 near the funnel wall at a distance from the electron gun assembly 27 arranged and attached to the anode 45. On the one facing the funnel wall Side of the getter element 75 is an insulating cover 79 so attached that there is mechanical contact with the lining 39. The getter design is also conceivable 73 to be arranged with a longer support member 77 that the getter element on Pad 33 is applied with low resistance. The insulating cover 79 has the task how to prevent precipitation of getter material on the contacting funnel wall also the formation of an electrical short circuit between the metallic getter element 75, which has anode potential, and the conductive coating 39 or 33. Such getter arrangements are known per se from US Pat. No. 3,390,758.

The getter element 75 used here has a diffusion direction generator 81, which forms a unit with the outer edge of the annular getter element 75. As in the previous example, the diffusion direction generator 81 has a overlapping interruption 83 to avoid unwanted RF coupling and heating during to avoid activation of the getter material. The positioning of the getter formation 75 is critical as it is difficult to obstruct electron beams avoid.

Figures 6 and 7 show a further embodiment of the arrangement a getter formation 85 similar to the first exemplary embodiment on the anode 45 assembled. Here, however, the diffusion direction generator 91 is as in the second example attached conically to the getter element 87 and the insulating cover is missing. The electron beams pass the opening of the getter formation 85 centrally without with optimal adjustment Disability. The diffusion direction generator 91 has an overlapping interruption 93 for the reason explained above.

While the described embodiments are currently the optimal Represent embodiments of the invention, it will be possible for the skilled person to further Develop refinements and variations that, however, reflect the inventive concept do not leave.

Claims (9)

Patent claims: 0 device to suppress flashovers in cathode ray tubes, the tube having a conductive coating in the funnel portion which is in proximity of the screen in the closure zone begins to extend up to or into the neck part extends and is at shield potential, and wherein an outer conductive coating the funnel part is provided, which begins in the closure zone and extends over extends the central region of the funnel part and leaves space in a recess for the usual high-voltage bushing, characterized by the following Combination of measures: A. A conductive coating (33) with low resistance is applied to the inner wall of the funnel part (15), has an electrical connection with the high-voltage connection (35) and extends from the closure zone (19) up to the imaginary level (31) - ,, similar to the expansion of the outer covering (29)) B. A conductive lining (39) with high resistance joins the lining (33) and is uniformly glued to the inner wall of the funnel part (15). It extends into the neck part (13) and has a skirt-shaped training and an abrasion-resistant and particle-free surface. In the neck part (13) forms the Cover (39) electrical contact with the anode or end electrode via contact clip (49) (45) the electron gun assembly (27), C. At least getter training (51; 63; 73; 85) is inside by means of one or more support members (55; 67; 77; 89) attached to the tube and has an integrated diffusion direction generator (5> 71> 81, 91), which is ring-shaped like the actual getter element (53> 65> 75; 87) is formed. 2. Device according to claim 1, characterized in that the covering (39) with high resistance from a sinter-base mixture which fuses during heat treatment with glass, the one with the glass of the funnel part (15) and neck part (13) enters into an intimate bond. 3. Device according to claim 1, characterized in that the getter formation (51) has an annular getter element (53) which is attached to the anode (45) by means of the support members (55) is attached, and that on the inner edge of the getter element (53) an diffusion direction transmitter (57) attached with a ring-like, arched umbrella shape with its outer edge pointing back into the neck part (13). 4. Device according to claim 3, characterized in that the diffusion direction generator (57) is not seamless, but is provided with at least one overlap (59), which runs approximately radially. 5. Device according to claim 1, characterized in that the getter formation (73; 85) has an annular getter element (75; 87), which is attached to the anode t45) by means of the support members (77; 89), and that on Outer edge of the getter element (75; 87) .a diffusion direction transmitter (81; 913 attached is that conically widening roughly in the direction of the electron beams is arranged towards the screen (21). 6. Device according to claim 5, characterized in that the diffusion direction generator (81> 913 not seamless, but provided with at least one overlap (83; 93) is, which runs approximately radially. 7. Device according to claim 1, characterized in that the getter training (73) attached to the anode (45) by means of a curved, elongated support member (77) and abuts the wall of the funnel part (15) with only one insulating material cover (79) touches the coating (39), the one on the diffusion direction generator (81) opposite Side of the getter element (75) is attached, and the diffusion direction generator (81) is integrated with the outer edge of the getter element (75) and so into the interior the tube obliquely in the direction of the screen (21) and thus away from the covering (39) is directed. 8. Device according to claim 7, characterized in that the diffusion direction generator (61) is not seamless; but with at least one overlap (83) is provided, which runs approximately radially. 9. Device according to claim 1, wherein the cathode ray tube is a color picture tube is formed with a shadow mask, characterized in that the getter formation (63) by means of a resilient support member t67) contains a getter element (75) which near the front hopper wall (as Figure 1 shows) in the Proximity of the closure (19) outside the writing area of the electron beams is arranged that the support member (67) is mounted on the frame (69) of the shadow mask (23) is that the getter element (65) towards the interior of the tube with an obliquely attached, leaf-shaped shield is provided as a diffusion direction generator (71), which the effusion directs to the shadow mask (23) and the screen (21), and that on the back a cover (73) made of insulating material is attached to the getter element (65), which thus prevents the effusion of the getter material directly to the covering (33).