DE1163987B - Implosion protection device for a cathode ray tube - Google Patents

Description

Implosion protection device for a cathode ray tube The invention refers to an implosion protection device for a cathode ray tube, are provided with a conductive coating on the outside and inside of the cone, consisting of two mechanically interconnected metallic frame parts, which firmly surround the tube in the area of its greatest circumference, especially for picture tubes.

It is already known in the case of picture tubes that are adjacent to the front panel To surround wall area with a one-piece or multi-part metallic frame. This frame forms the perimeter of the image window and partially covers it the conical wall part of the tube and serves at the same time for fastening the tube in a housing, generally in such a way that the faceplate and a part of the frame delimiting the picture window protrudes freely from the housing. The space between the frame and the tube wall is usually with a solidified Potting compound filled.

In the case of such implosion-protected picture tubes, special precautions must be taken are taken to protect the user from harmful touch voltages, as it is known that a conductive coating is applied to the outer wall of the cone of the tube that can carry dangerous contact voltage and sufficient insulation of the metal frame from the conductive covering e.g. B. due to accumulation of dust on the Duration is not guaranteed.

Such a picture tube protected against implosion is safe to touch formed when, according to the invention, the two frame parts with the interposition of insulating material are connected to each other and if the cathode-side frame part is electrically connected to the conductive outer covering.

On the basis of the FIGS. 1 to 4 illustrated embodiments the device described is explained in more detail below: F i g. 1 shows a Part of a picture tube with the front window 5 and the conical wall part 6. Im The area of the greatest circumference of the tube is that of two parts 1 and 2 Arranged frame that surrounds the tube on its entire circumference. The two metallic ones Frame parts 1 and 2 can for example with the help of the flanges 8 and 9 with each other be connected. The space between the frame parts and the tube wall is in generally filled with an insulating potting compound 7.

The two frame parts are made by inserting an insulating part 4 galvanically isolated from each other. The insulating part 4, for example the in the F i g. 2 may have the shape shown, can be made of pressboard or another suitable insulating material. It is expediently made so large that that its outer edge protrudes beyond the ends of the flanges 8 and 9 to thereby to obtain a sufficiently large creepage distance. This isolation can be for reasons an efficient production, possibly composed of several subsections be.

The cone-side frame part 2 is connected to the ground point of the device. This is generally also the case with the outer, electrically conductive covering 10 tied together.

It should be noted that the mass point is definitely a life-threatening one Voltage to earth can lead, as such devices are generally known as universal current devices are switched. Since the front frame part 1 can be touched by the user, is to ensure that at least this frame part 1 against the ground point the device is isolated.

Attempts have been made to galvanically connect the two frame parts to one another to connect and the frame electrically with the ground potential via an RC element connect to. The circuit resulting from this arrangement is shown in FIG. 3 shown. With 1 and 2 the two frame parts are galvanically connected to one another designated. Cl and C2 mean the between the frame parts 1 and 2 and the Inner, electrically conductive coating 3, which is at anode voltage, results in capacitances. C3 and R are the switching elements of the RC element in the ground line. The frame parts 1 and 2 lead a potential that is essentially through the capacitive Voltage divider (Cl + Cz) is given in series with C3. With themselves In practice, the capacities Cl and C, which are set, must now be C, relatively large be dimensioned so that the potential of the frame parts 1 and 2 in the vicinity of the ground potential lies. On the other hand, C3 cannot be made arbitrarily large, because otherwise the contact security is no longer guaranteed. The maximum allowable value of C3 is about 5000 picofarads, because the mass point is life-threatening voltages can lead to earth. Another disadvantage of this circuit is that the effective capacitance between the coating 3, which is at anode potential, and the Ground point is reduced, which is undesirable for reasons of anode voltage screening is.

In Fig. 4 shows the circuit diagram for the arrangement described. The frame parts 1 and 2 are no longer galvanic, but with one another via an RC element tied together. The frame part t is connected directly to ground, as it is within the Device lies and cannot be touched. The potential of the frame part 1 is essentially given by the voltage divider Cl in series with C3, from which one it can be seen that in the described arrangement with a smaller capacitance C, gets by as in the circuit according to FIG. 3 assuming the same tension. Furthermore, the capacity C., can be fully utilized for anode voltage sieving. The resistor R3 is used to dissipate static charges and is for safety reasons larger than 300 kilo ohms.

The capacitive connection of the two frame parts can be made by appropriate Formation of the two flanges 8 and 9 can be achieved, while the resistor R3 can be formed by a suitably prepared filling compound 7. So can the Filling compound 7 contains graphite, for example, at least in the area of the flange connection, making it slightly conductive.

Claims (7)

Claims: 1. Implosion protection device for a cathode ray tube, with a conductive coating on the outside and inside of the cone. are provided consisting of two mecha: metallic frame parts connected to one another, which firmly surround the tube in the area of its greatest circumference, characterized in that that the two frame parts (1, 2) with the interposition of insulating material (4) with one another are connected and that the cathode-side frame part (2) with the conductive outer covering (10) is electrically connected. 2. Implosion protection device according to claim 1, characterized in that the frame parts have a flange. 3. Implosion protection device according to claim 1 or 2, characterized in that the two frame parts are capacitive are connected to each other. 4. Implosion protection device according to claim 2 or 3, characterized in that the capacity through the flanges of the frame parts and the insulating material interposed therebetween is formed. 5. Implosion protection device according to claim 3 or 4, characterized in that the capacitance is a resistor greater than 300 kiloohms is connected in parallel. 6. Implosion protection device according to Claim 5, characterized in that between the frame parts and the tube wall a potting compound is provided, which by additives such. B. graphite, weakly conductive is made. 7. Implosion protection device according to claim 4, characterized in that that between the flanges a flat, one-piece or multi-part ring made of insulating material is provided.