DE1855480U - TELEVISION TUBE. - Google Patents

Description

"Television tube" The innovation relates to television tubes made of glass.

TV tubes are known to consist of a piston that consists of a Screen and a component called a cone of basically conical shape Shape is assembled with the union of these parts at their edges.

The one equipped with their internal organs, especially the so-called "cannon" evacuated flask forms the television tube.

TV tubes are known to be at risk of a sudden, referred to as "implosion" Breakage, which leads to the hurling of glass splinters. The ones in the Manufacturing facilities of the tubes are employed both during the evacuation of the tube, as well as during the further manufacturing and control of the danger of injuries from this Glass splinters exposed. Also in the Manufacturing facilities in which the tubes are inserted into their housings can in the case of implosions, the thrown glass splinters those who work there hurt. After all, this can cause splinters of glass when using the television not only are the receiving and reproducing organs destroyed, but they mean also endangering the television itself, which makes it necessary to pass this through to protect a safety disc placed in front of the screen. Furthermore, both in the manufacture of the tubes as well as in the assembly of the entire apparatus through the Implosion thrown glass splinters in turn to implosion from neighboring ones Tubes ("secondary implosions) and lead to considerable damage to property.

The innovation avoids these disadvantages.

The subject of the innovation is one that is not capable of implosion and therefore a cover plate to protect against the risk of implosion, which is not required by cathode ray tubes, in particular television tubes whose pistons consist of a screen and a screen that is welded to it Cone consists, and those with a rigid, which between the essentially through the perimeter of the screen, in which the weld is located, and a plane that is near the largest diameter of the cone, lying Zone surrounding belt is provided.

In the case of the television tubes designed according to the innovation, a unintentional intermittent mechanical or thermal stress on any Place of the surface of the tube or also a? Fatigue as a result of a surface defect. s, generally speaking, any of the phenomena leading to implosion would lead to an unprotected tube, not one of a surging Glass splinters accompanied the abrupt breaking of the same, but it is through this rigid belt-i-1 in contrast to the propagation of the cracks in the Vitreous which is the result of accidental impact or fatigue are considerably slowed down and a pressure equalization between the outside air without implosion and the inside of the tube ensured.

The rigid belt consists of either one element or a plurality or the entirety of those that cling to the shape of the tube.

According to a particularly advantageous embodiment of the innovation the belt of one or a set of external elements and one between these and the tube arranged non-compressible and non-expandable Intermediate material that fills the entire space between the two surfaces and in contact or at least substantially in contact with both the tube as located with the outer element.

This embodiment of the innovation is particularly suitable for outer members formed by a pair of shells. According to one embodiment the cathode ray tube according to the innovation is the rigid belt on the evacuated The tube is placed in such a way that it is on the whole or on the largest Part of the zone covered by it, in contact with, the surface of the Tube jacket is located and no compressive stress on the surface of the tube jacket exercises.

The evacuated tube in particular can be used to attach this belt in a vertical position on one of the shells forming the rigid belt part with the interposition a seal placed between the tube and this shell and on this shell the other shell is attached, whereupon in the space between the shells and the tube is filled or poured with the intermediate material that is currently its penetration can be solid, liquid or powdery.

The trays can be made of metal, metal alloys, glass or glass fiber reinforced Plastics, generally made of any material. the appropriate mechanical Has properties, particularly from the point of view of rigidity.

As between. the shells and tubes brought in in-liquid state Intermediate material can be sulfur. Synthetic resins, cements, metal alloys, etc., anyway Substances that meet the requirement that after pouring without Volume increase solidify, be used.

The innovation also includes an embodiment which makes it possible the danger of the occurrence of the implosion phenomenon not only after evacuation of the tubes, but also to be switched off during the evacuation process.

In this embodiment, the non-deformable, from one or multiple element belts on the tube before evacuating the same upset.

It was found that in the process of evacuating the television tube by the action of the external atmospheric pressure the piston of the tube is in a zone substantially between one by the perimeter of the screen or adjacent to the viewing zone and one of the larger diameter base of the cone The running plane is a little stretching out. This expansion of the piston in the girdled Zone at the time of evacuation of the tube causes good contact between the butt and the belt.

The details and further features and advantages of the innovation emerge from the following description of some embodiments of the new cathode ray tube and the method for their production, in particular those in which the belt consists of a pair of "shells," according to the Illustrations.

Figures 1 to 3 represent in axial section embodiments of cathode ray tubes equipped with a belt according to the innovation.

Figures 4 to 11 illustrate the various stages of manufacture of such tubes.

FIG. 12 schematically shows the overall arrangement of an installation for oversight the tubes with the belt according to the innovation.

FIG. 13 is a vertical section through one of the devices from FIG which this facility exists.

FIG. 14 shows, in vertical section, a boiler for melting sulfur, which is inserted between the shells and the tubular body.

Figure 15 illustrates another embodiment of a television tube according to the innovation in which the rigid belt before evacuation of the piston is applied to this.

The tube shown in Figures 1 to 3 consists of a screen 1 and a cone 2, which are welded to one another along line 3. The one to be girdled Zone lies between lines 4 and 5, one of which is the perimeter of the viewing zone of the And the other near the base of the largest diameter of the cone.

The belt, which consists of an outer element, is arranged around this zone 6 z. B. consists of metal that essentially hugs the shape of the zone, however, it leaves a gap created by a non-expandable intermediate material 7, e.g. B. a thermosetting resin, a fiberglass-resin-cement material o. Like. Is filled out.

In the embodiment shown in Figure 2, there is the outer element of two metallic elements 6 and 6, which are essentially produced by dishing 6a bracketed together.

In the embodiment shown in Figure 3, there is the outer element from two metallic castings 6,6a, which are connected to each other z. B. by screws or Bolts are connected.

Figure 4 shows a carrier 11 with centering fingers 12, of which generally four are provided.

On this carrier, the shell 13, which is on the screen side of the Tube is to be attached (shield shell) and a seal 14 on its circumference has been attached (Fig. 5).

Then (FIG. 6) the tube 5 becomes diagonal with the interposition of itself Opposite centering plate 16 inserted into the shield shell (Fig. 7).

Now (Figure 8) the shell 17 (conical shell) on the Centering finger 12 put on and thereby secured in their place.

The two shells 13, 14 are (Figure 9) by electrical welding firmly connected to one another by means of welding tongs 18.

The tube is sealed against the seal 14 (FIG 10) by screwing, which are screwed in through the holes in the shells and support on the tube.

Then the intermediate material, such as. B. liquid sulfur, via a pipe 20 which is fed from a melting vessel 21, poured. After complete solidification the sulfur fills ! f this to the gap 22 and secures the rigid connection dung between the shells and the tube without affecting them a pressure is exerted. The tube is now removed from the carrier.

The system shown schematically in Figure 12 enables this Processes continuously at a succession of stations, e.g. B. six stations A, B, C, D, E and F arranged around a ring table h.

This system has a conveyor 23, which passes through a Vorerwärmüngskanal 24 runs, in which a temperature of 60 to 80 C is maintained, and who feeds the pods, as well as a. also through a preheating channel 26, in which a temperature of 60 to 800 0 is maintained Conveyor 25 that feeds the tubes 15 on.

The turntable 13 consists (Figure 13) of one. mounted on feet 28 fixed ring 27, and a ring resting on this via balls 30 and rotating 29. The six supports 11 for the various stations are on this rotating ring attached evenly over the circumference. These supports are around journal bearings 31, which are firmly connected to the ring 29, pivotable. On the rotating wreath handles 32 are attached, which allow its rotation .. The definition the ring in the respective position is carried out by means of a pedal 34 actuated pin 33.

The facility also has welding tongs. 18, a melting kettle 21 for the sulfur and suction devices 35 on.

As can be seen from Figure 14, there is the melting vessel for the Sulfur from a double-walled vat. In the space between the two walls 36,37 electrical heating elements 38 are accommodated. '. The melting temperature can can be set by the thermostat 39-.

At the top of the melting vessel is a hopper 40 arranged, from which, controllable by the flap 41, the melting container with sulfur flower is charged. One above of the molten bath 43 arranged Sieve 42 ZXRNNX slows down the outflow of sulfur flowers. The gases escape through e. a discharge line 44.

The pipe 20 for the introduction of the molten sulfur between the bowls and the tube is via the faucet 45 to the lower part of the melting kettle 21 connected.

This takes place at station C of the system shown in FIG Attaching the locking screws 19 in the conical shell 19 and inserting the Seal 14 in the shield shell 13.

The tubes and dishes heated to around 60 to 800 C are successive subject to the various operations listed below: on the Station A the operations shown in Figures 6, 7 and 8, at the station B the welding shown in Figure 9, at station 0 that in the figures 10 to 11 work processes illustrated, at stations D and B the complete one takes place Solidification of the sulfur with cooling by suction air, and at the Station F the removal of the tube protected by the belt from the carrier and centering the shield shell on the carrier (Figure 5). The one with the protective belt provided tubes are discharged by a conveyor 46.

In the case of the one shown in FIG. Embodiment is that of 'one Screen 1 and a cone 2 formed piston with one made of metal elements and one Intermediate element that can withstand the thermal stresses caused by the tube during its Is subjected to evacuation and the z. B. a softening point above 4000 C, achieve, is resistant to, formed belt provided.

Such a material can advantageously be copper chloride. According to FIG. 15, the belt consists of two shells 6 and 6a and the intermediate material 7th

In addition to the advantages of the belt according to the innovation already explained above, there are others in the simple attachment of the tube in its carpentered housing, e.g. B. by using the flanges provided according to FIGS. 2 and 3 for this purpose. The screen-side edge of the belt can also be decorated which is also used for attaching SBKxxEkijaHgEE for the shield be turned. The innovation is not on cathode ray television tubes limited, but also applicable to all other types of cathode rays, the bulb of which consists of a screen and a cone that are welded together, such as. B.

Radar or oscilloscope tubes.

Protection claims:

Claims (1)

Protection claims: 1. Cathode ray television tube without front protective screen against the risk of implosion, the pistons of which were welded together from a screen and a screen The cone is characterized in that it is on both sides of the weld seam with one between the one running essentially through the perimeter of the screen certain plane and one of the base area adjacent to the largest diameter of the cone lying plane lying zone of the piston surrounding rigid belt is provided, which practically does not exert any compressive stress on the surface of the tube piston. 2. Cathode ray tube according to claim 1, characterized in that that the rigid belt consists of one element, a plurality, or an assembly of the shape of the tube is made of elements nestling. 3. Cathode ray tube according to claim 2, characterized in that that the belt consists of an external element or an assembly of external elements and one connected between these and the tube non-compressible and non-stretchable fabric. 4. Cathode ray tube according to one of claims 1 to 3, characterized characterized in that the outer element consists of one or more on the tube, e.g. B. by clipping together or by flanging with screws and bolts connected shells. 5. cathode ray tube according to claim 3 and 4, characterized in that that the intermediate material consists of a pourable and solidifies without expansion Substance is made. 6. cathode ray tube according to claim 4, characterized in that that the shells are provided with stiffening ribs which, if necessary, the Form contact surfaces between the shells and serve to connect them to one another. 7. Cathode ray tube according to one or more of the preceding claims, characterized in that the rigid belt of one or more external elements and one that is not Compressible and expandable intermediate material which has been attached between the tube and the outer element or elements after the tube has been evacuated. 8. Cathode ray tube according to one of the preceding claims, characterized in that the intermediate material consists of sulfur consists. , 9. Piston for making a cathode ray tube according to a of claims 1 to 6, characterized in that the rigid - Belt applied to the tube that has not yet been evacuated. is. 10. Piston according to claim 9, characterized in that the belt from one or more outer elements and a temperature-resistant intermediate material, for example copper chloride. 11. Cathode ray tube according to one of claims l to 8, characterized characterized in that the shells are connected to one another by electrical welding are. 12 * Device for holding the cathode ray tubes for the purpose of attachment of the belt in a vertical position, characterized by a support body on which one of the two shells forming the belt is put on, which is then interposed a seal carries the tube. 13. The apparatus according to claim 12, characterized in that the seal on the tube by screwed into the shell screw ben, which are supported on the tube, is supported. 7th 14. The device according to claim 12, characterized in that the support body has fingers which engage in bores of the shells placed on it. 15. Device for the assembly of television tubes according to claims 1 to 14, characterized by a succession of a turntable surrounding work stations, at each of which one or several operations are carried out. 16. The device according to claim 15, characterized by a melting cauldron from which the in the cauldron in the form of sulfur flower introduced sulfur is poured into the space between the shells and the tube after melting and which has a double heating wall to regulate its temperature.