DE257972C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

- JVl 257972 - CLASS 21 /. GROUP

OTTO SCHALLER in BERLIN-SÜDENDE. Electric lamp.

Addition to patent 243990.

Patented in the German Empire on August 24, 1912. Longest duration: July 13, 1925.

In patent specification 243990 there are only such Embodiments of the electric lamp protected by that patent for illustration arrives in which the vertical center axes of the sealing surfaces of the power supply lines lie parallel to one another, so that the pressure forces of the atmospheric air which support the sealing of the lamp are parallel and are directed in the same way.

'10 Now, however, been found another embodiment particularly advantageous. In this embodiment of the invention, the vertical axes of the sealing surfaces coincide or they converge. Therefore, these compressive forces are opposite or so directed that they converge on each other. As a result, the manufacturing costs can be reduced, the seals can be improved and simpler shapes can be selected for the lamp parts.

In the example shown in FIG. 1, a ring f made of electrically conductive material is placed on the edge of the bell jar a, which is open at the top, in an airtight manner by means of the sealing ring d ' , and this ring carries, with the intermediation of a second sealing ring d, a somewhat shaped dome g made of electrically conductive material . The upper sealing ring d must be made of insulating material. The current-conducting parts f and g carry the sealing surfaces and 35 which are used for sealing on the lamp

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form laterally protruding parts of the power supply lines c to the filament b. The power supply lines c can be permanently or detachably connected to their parts f or g used for sealing.

Fig. 2 shows the same embodiment in another predominantly cylindrical lamp shape, the ι arched position shown in Fig. Electroconductive tip g is replaced by a flat lid and the stromkjtende ring f instead of the H-förrnigen cross-section of a rectangular cross section has received. It is to be shown in how many ways the arrangement of the two seals can be made, and that it does not depend on the shape of the lamp, the sealing surfaces and the conductors that carry them and are connected to the power supply lines c.

Another example is shown in FIGS. 3 and 4 in longitudinal section and plan, wherein the right and left side of Fig. 3 two different designs for the seals demonstrate.

The lamp bell consists of two spherical caps a _x and a ₂ , z. B. two hemispheres. However, the two domes can also be of different sizes. The upper dome U ₁ is sealed at its edge against the current-conducting ring g, the lower dome S ₂ also against the current-conducting ring /.

(2.

, issued April 26, 1913)

Both rings are sealed against each other by the insulation ring d, which can be made of glass or some other non-conductive material. The power supply lines c to one or more filaments b are again conductively connected to the rings g and f. The filaments can be connected individually in parallel or in series or in groups in parallel and in series.

ίο The seal drawn on the left in Fig. 3 differs from the one drawn on the right in that the conductive rings f and g have received an H-shaped cross-section so that they can accommodate the sealing rings h , the material of which can be conductive or non-conductive, while in the illustration on the right-hand side, the sealing rings themselves also serve as current conductors.

A star-shaped arrangement is chosen here as an example for the arrangement of the filaments b , with the power supply being on the one hand through the bridge c connected to g to the central connector e, on the other hand from the ring f to the ends of the filaments connected to it. The upper dome a _x can be designed as a reflector. The parallel connection of the filaments also offers the advantage that the breakage of a filament does not render the lamp inoperable.

The sealing requires the greatest care. All known substances, agents and processes can be used for this, in particular those mentioned in patent specification 243990. The arrangement of the seals selected, for example, in FIGS. 1 to 4, however, allows the use of a common seal on the outside or next to them, which is shown schematically in FIG. A glass ring r is fused to the lower lamp part a ₂ or is attached in some other way to the container in such a way that an annular cavity is created which seals the strpmleitenden parts f and g against the lamp parts a _x and a ₂ , as well as against the insulation ring d towers above, and which is filled with oil or other insulating sealant. As a seal between metal and glass, rubber, impregnated paper and other sealing means have proven to be sufficiently airtight, but it has been shown that the lamp cover gradually heats up without the filaments oxidizing. The inventor concludes from this that, although air is not admitted from the outside, oxygen-free gases develop inside the lamp, and he sees the cause of this in the release of gas by the sealing means. It is therefore advisable to only use sealants that do not emit gases. If you use metal, e.g. B.

Lead, as a condition for a good seal, is at least temporary use a pressure at which the sealant begins to flow because then it fills the smallest bumps in the surfaces to be sealed. This condition can be by simply screwing them in, not in all cases with certainty, partly because of the The pressure at the screw connection is not completely uniform, partly because of changes in temperature the screwing means experience a change in size, namely a different one than the sealing means.

In the present arrangement of the seals and the dimensions of the hochkerzigen lamps, it can be achieved that the sealing surfaces already received by the λ evacuation of the lamp a pressure of \ many kilograms per square centimeter 80 ™. In that regard, this pressure is not sufficient to bring the sealing metal to flow \, it may be supplemented in a compressor up to the required height. So z. B. a spherical lamp of 30 cm outer diameter with annular sealing surfaces 3 mm wide at its equator when evacuated a pressure of 25 kg per square centimeter of sealing surface, so that it would be sufficient in a compressor to a temporary overpressure of only one. exposing it to a few atmospheres to obtain sufficient pressure to flow a lead seal. In this case, heating can also be carried out in order to make the sealing material softer or to be able to keep the pressure lower. (

The conductors to be sealed against the non-conductive material can also be made of metal or the otherwise chosen sealant, but they can also with provided with a metal coating (leaded, gold-plated, etc.) or covered with a metal foil be.

Metal seals made in this way can withstand temperature changes very well well, they follow the expansions of the lamp, they breathe, as the saying goes, unscathed their poetic effect.

In all the prescribed embodiments, the sealing surfaces have a common axis. It is not necessary that these sealing surfaces are close to one another. They can even be located at opposite points on the lamp, as the tube lamp shown schematically in FIG. 6 shows as an example. The type of seal itself is not shown. The covers g and f can also be made of a conductive material that seals itself. The direction of the compressive forces is

indicated by arrows. An example of a lamp in which the axes of the sealing surfaces and thus the pressure forces also converge, as the arrows indicate, is shown in FIG. 7 in the form of a curved tube lamp also schematically and without regard to the Type of seal reproduced.

It can be seen that these examples can be multiplied at will.

The type of connection is also irrelevant to the subject matter of the present invention the filaments or incandescent bodies with the conductors.

Claims (7)

Patent claims: 1. Electric lamp according to Patent 243990, characterized in that the vertical Central axes of the sealing surfaces coincide or converge, 2. Lamp according to claim 1, characterized in that for the sealing surfaces Both current conductors a common liquid seal is arranged in addition to the seal by the air pressure. 3. Lamp according to claim i, characterized in that the sealing means Lead or another metal is used. 4. Lamp according to claim 1, characterized in that the conductor itself serve as a sealant. 5. Lamp according to claim 1, characterized in that several filaments are star-shaped are arranged, wherein the center of the star is connected to one conductor, while the other conductor includes the ends of the filaments. 6. The method for producing the lamp according to claim 1, characterized in that that the lamp is temporarily brought under external pressure. 7. The method for producing the lamp according to claim 1, characterized dadurcli, that the sealant is temporarily heated. 1 sheet of drawings.