DE2039504B2 - Glass bulb for a world-angle television picture tube - Google Patents

Description

The invention relates to a glass bulb for a wide-angle television picture tube made of a funnel-shaped Part, a tubular neck part formed on its narrower end and one with its further end connected approximately rectangular front plate, wherein the funnel-shaped part is a pair from the short sides of the front panel, outwardly curved, opposite one another Side walls and a pair of opposing sides adjoining the long sides of the faceplate Side walls that enclose an angle of over 90 °.

Such a glass bulb for a wide-angle television picture tube is known, for example, from US Pat. No. 3005122. As can be seen in particular from FIGS. 1 and 6 of this publication, in this known piston all the side walls of the funnel-shaped part are curved outward. In the case of glass bulbs for wide-angle television picture tubes, a high concentration of stress has been found in the yoke area of the funnel-shaped part adjoining the neck part. It is known that such pistons are evacuated after manufacture, so that the atmospheric pressure on the piston walls causes corresponding compressive or tensile stresses in the glass body. These tensions reach peak values in the yoke area mentioned, since at this point the side walls of the funnel-shaped part merge into the tubular neck part via a strongly curved area. It was previously of the opinion that such stress peaks could be reduced by increasing the curvature of the side walls of the funnel-shaped part and thus the strength of the funnel-shaped part could be increased, but this method could not achieve significantly improved strength properties.

The invention is based on the object of providing a glass bulb for a wide-angle television picture tube create in the evacuated state. Jes KoI-, " bens in the yoke area occurring compressive and tensile stresses are lower than with conventionally designed Pistons.

This object is achieved according to the invention in a glass bulb described at the outset by ,, that the connecting to the long sides of the front panel Sidewalls are practically flat in their middle area and flow into the edges at their edges pass over subsequent sections of the piston.

, “Surprisingly, through training of practically flat areas in the side walls adjoining the long sides of the front panel of the funnel-shaped part a considerable reduction in the compressive or tensile stress that occurs -, - gene achieved.

Advantageously, the flat areas are triangular in shape. This embodiment is expediently designed so that an angle of the triangular areas points to the neck part and that _{) ()} the side of the area opposite this angle runs approximately parallel to the long side of the front panel.

The invention is explained below using an exemplary embodiment in conjunction with the drawing ,. explained. It shows

1 shows a glass bulb in a perspective view from the front,

2 shows a perspective illustration of a cut-open part of the piston shown in FIG. 1, _m FIG. 3 shows a side view, partly in section, of the piston of FIGS. 1 and 2,

Fig. 4 shows two outlines of a conventional one Piston, and

Fig. S a two contour lines according to the invention _n formed piston.

In Fig. 2, the glass bulb is shown in section, the known shape by a The dash-dotted line is indicated and the practically flat area is shown in the hatched cross-section

"Λ ^iSt ·

As can be seen in particular from FIGS. 1-3, the glass bulb 10 is funnel-shaped Part 11 to which a front plate 16 and a tubular Neck part 15 are integrally formed. The long hori-

.. zontal axis and the short vertical axis of the front panel are shown in Figs. 1 and 2 and are only shown below as a long axis and designated short axis. The funnel-shaped part 11 is provided with an extending from the neck part 15,

_h0 is provided in the direction of the front plate 16 widening yoke area 12. In order to obtain the shortest possible piston length, the length "ti" of the piston from the front plate 16 to the edge of the neck part 15 is compared to known embodiments

_{b5 has} been shortened considerably. To achieve this shorter knee length, the walls of the funnel-shaped part diverge very strongly, so that a so-called wide-angle tube is obtained in which the

on the long sides of the front plate adjoining, opposite side walls of the funnel-shaped Partly enclose an angle of over 90 °, these side walls each have a central, practically flat area 13, the edges of which flow into the adjoining sections of the piston pass over. In Fig. 2, a side wall profile is shown in detail, with the dash-dotted line Line 17 indicates the profile of a known funnel-shaped part of conventional construction.

The strength properties of the piston are shown by analyzing the stress distribution. For this purpose, flasks of conventional wide-angle television picture tubes were evacuated, and the voltages generated thereby were analyzed by means of tension meters which were arranged at points which are designated A, B, C, D and E in the profiles shown in FIGS . It was found that very high tensile stresses occurred at point A in the yoke area and very high compressive stresses occurred at point D in the yoke area.

The conventionally designed piston has such a shape that the normally Bending forces occurring in the area of the short axis generated tensile stresses due to the direct Pressure load can be suppressed. When the construction is changed in the way would that the bending stresses could be transferred to the short axis, would be a stress breakdown take place inside the piston and thus reduce the pressure load on the short axis so that a significant reduction in tensile stress in the yoke area of the long axis would be obtained. Thus, this change leads to the creation of low tensile stresses in the vicinity of the front panel edge. However, these stresses are not so high that they affect the strength of the piston decrease in some way. Such a stress reclassification is practically flat Areas achieved. By means of the increase in the tensile load achieved in the area of the short axis and reducing the compressive load in the area of the long axis, the tensile stress in de.i becomes critical Areas, d. H. in the yoke area of the long axis, reduced to an acceptable value.

The table below shows the results of the tests on a conventional piston for a wide-angle television picture tube and the results of the investigations on one according to the invention trained piston executed. Both flasks are made of glass.

Tensions in the evacuated flask

Conventional According to the Invention

Piston formed piston

A. + 118.1 at + 20.4 at B. - 91.4 at - 80.8 at C. -112.5 at - 67.5 at D. -104.7 at -17.57 at E. - 9.14 at + 48.5 at

(+) = Pull (-) = push

An analysis of the stress distribution shows that at the point marked D in Fig. 4 in the conventionally designed piston, high pressure fluctuations

Ii nings occur. At the same time, compressive stresses also occur at point E of the short axis near the edge of the front panel. This state of stress leads to high stresses in the area of the long axis, which is shown by the high compressive stress at point B and the high tensile stress at point A.

From a comparison of the results it can be seen that with the construction according to the invention at point A, which is approximately parallel to the front panel

The yoke area extending along the vertical axis corresponds to about six times less tensile stress than in the conventional construction and at point D, which corresponds to a yoke area extending approximately parallel to the horizontal axis of the front plate.

ju speaks, can achieve a compressive stress about six times lower than with the conventional construction. This also results in points C and E near the front panel edge and in the middle area B on the short side of the

j> Front panel adjoining side wall considerably more favorable voltage values.

The better stress distribution in the novel construction was also achieved in other ways Pressure tests on finished pistons proven. During these pressure tests, the piston was inside exposed a chamber to slowly increasing hydrostatic pressure until a rupture occurred. at conventional pistons examined in this way occurred at a mean of

-ι-, 1.54 atü fractures in the yoke area.

In contrast, pistons produced according to the invention held pressures of more than 4.2 atmospheres without the occurrence of breaks in the critical yoke area. If any of these pistons failed, it found it

-> o not in the critical yoke area and when it is satisfactory Strength values.

To do this, draw 2 sheets of paper

Claims (3)

Claims; 1. Glass bulb for a wide-angle television picture tube from a funnel-shaped part, a tubular part molded onto its narrower end Neck part and an approximately rectangular front plate connected to its further end, wherein the funnel-shaped part is a pair of adjoining the short sides of the front panel, outwardly curved, opposing side walls and a pair of on the long sides the front panel adjoining, opposing side walls that form an angle of Include over 90 °, characterized in that the on the long sides of the Front panel adjoining side walls in their central area (13) are practically flat and on their edges merge smoothly into the adjoining sections of the piston. 2. Glass bulb according to claim 1, characterized in that that the flat areas (13) are triangular. 3. Glass bulb according to claim 2, characterized in that an angle of the triangular Areas (13) to the neck part and that this angle opposite side of the area (13) runs approximately parallel to the long side (14) of the front panel.