DE1067930B - - Google Patents

Description

The invention relates to an electric incandescent lamp with a gas-tight sealed bulb and a double-coiled thread, the longitudinal axis of which essentially coincides with the longitudinal axis of the piston, and a method for manufacturing such incandescent lamps.

It is known to increase the efficiency of gas-filled incandescent lamps, the filament spatially concentrate as much as possible. The known double helix shape has proven particularly useful for this proven. It has now been shown that a further noticeable improvement can be achieved in that the thread structure is chosen so that the double helix is vertical during operation. You then get for one given nominal voltage a lower lamp current or a higher luminous efficacy. In addition to This increase in efficiency also results in a longer lamp life. The decrease of the current is due to an increase in the thread resistance, which in turn is due to an increase in the thread temperature is caused. The filling gas of the lamp thus exerts a vertical effect on you A standing thread has a lower cooling effect than a horizontal thread. The reason for the increased service life is apparently due to the fact that with a vertical thread through the in the immediate Tungsten partial pressure prevailing near the filament evaporates less filament metal than at a horizontal thread.

Incandescent lamps with a filament arranged in the longitudinal axis of the lamp are known. Lamps with axially arranged Filament must necessarily have a support arrangement in which the lead wires that carry the filament are of different lengths to have. If such an arrangement is made to vibrate, twisting or displacement occurs, especially if it is a more massive structure, as is the case with lamps of higher power, for example 200 watts and more is required. These mechanical twists can easily be a Bring damage to the very brittle filament. One has tried to overcome this difficulty by doing this To master that the supply ladder supporting the thread was made stronger, however this only made the difficulties worse.

Incandescent lamps are already known in which a bridge connecting the lead wires and holding the filament parts is provided, but in this case the individual filament parts, which are arranged parallel to themselves and parallel to the bulb axis, are connected in a meander shape. Incidentally, the lead wires connected by the bridge are of the same length; a reduction in the harmful effects caused by moving the holding electric light bulb
and methods of making them

Applicant:

General Electric Company,
Schenectady, Ν. Υ. (V. St. A.)

Representative: Dr.-Ing. Ε. Sommerfeld, patent attorney,
Munich 23, Dunantstr. 6th

Claimed priority: V. St. v. America October 14th and November 3rd, 1955

Charles Warren Pearson, Euclid, Ohio,
Paul Bruce Jordan and John William Anthony,
Cleveland Heights, Ohio (V. St. A.),
have been named as inventors

The known bridge arrangement does not cause any stinging of the individual filament parts possible.

The incandescent lamp according to the invention is intended to avoid the disadvantages of the known lamps. An electric incandescent lamp with a gas-tight sealed bulb and a double-spiral one Thread, the longitudinal axis of which essentially coincides with the longitudinal axis of the piston, and with two elongated, flexible lead wires of different lengths, which are anchored in the piston base and from this in the longitudinal direction on opposite sides of the piston longitudinal axis in the The interior of the piston extend to the vicinity of the corresponding thread ends and then to the longitudinal axis of the piston bent towards and at points in the piston longitudinal axis electrically and mechanically with the corresponding Thread ends are connected, is characterized according to the invention in that the transverse to the piston longitudinal axis, bent parts of the lead wires at or in the vicinity of their connection points are connected to one another in an insulating manner at the thread ends via a rigid bridge, which in the essentially perpendicular to the parts of the supply wires located in the longitudinal direction of the piston -

m 645/214

runs the plane, with the thread and the bent ends of the lead wires together with the bridge device form a rigid unit.

According to a further development of this arrangement, the rigid bridge arrangement can have an insulating intermediate part 5 , which connects the lead wires to each other at points near their connection points to the thread ends by an additional support wire is anchored at its one end, the other end around a central part of the Fadens to is looped around. The stress on the suture holder made rigid by the bridge can advantageously be reduced by an additional wire bracket which is attached at one end to an intermediate point of the longer lead wire and which is loosely anchored at its other end to the piston base between the lead wires, preferably in a hollow shaft protruding from the piston base between the supply wires.

By slightly changing the thread dimensions, you can achieve the advantage achieved entirely results in an increase in the efficiency by increasing the operating temperature of the thread while the service life remains the same as with threads operated in a horizontal position. Vice versa the structure can also be modified in such a way that the thread temperature and thus the efficiency remain the same as when operating in a horizontal position, while the service life of the lamp is increased accordingly will. The rigid unit formed by the bridge can, without a mutual displacement of the Ends of the lead wires and thus without causing stress on the filament, free swing.

The incandescent lamp according to the invention will now be explained in more detail with reference to the drawings means

Fig. 1 is a tilted or inclined elevation view of a lamp according to the invention; Fig. 2 is an elevation of another embodiment, Fig. 3 is a further embodiment,

FIGS. 4 to 10 are perspective views showing successive method steps in the production of the structure according to FIG. 3, which can be easily obtained with the aid of an automatic body manufacturing machine can be carried out, illustrate.

The lamp shown in Fig. 1 consists of a glass bulb 1 with a cylindrical neck part 2 and an inwardly protruding glass shaft 3 fused to its end. The piston 1 contains a Filling of an inert gas, for example argon or nitrogen or a mixture of both, with a pressure of several hundred millimeters Hg. A double-coiled tungsten thread 4 is from lead wires 5 and 6 supported so that its axis coincides with the longitudinal axis of the piston 1. the Lead wires 5 and 6 are partially melted into the flattened end 7 of the shaft 3 and from there to the outside to the corresponding contacts of the socket 8.

The elongated lead wires 5 and 6 are guided into the interior of the piston on both sides of the piston axis. Their inner ends 9 and 10 are bent sideways towards the piston axis and at the points where they meet the axis, clamped to the thread by means of hook-shaped bends 9 'and 10'. The lamp can also with a conventionally designed heat deflector 11, which is attached to the Shaft pressing part 7 is supported, be equipped.

The thread and its supporting structure, as far as described so far, can twist or distort, if the long and short lead wires 6 and 5 are different as a result of vibrations or shocks Experiencing transfers. Such distortions are caused by the lamp according to the invention avoided a bridging device that mechanically connects the inner ends 9 and 10 of the lead wires connects. In the embodiment shown, this bridge device consists of a pair of angled wires 12 and 13 through an insulating part 14, preferably a glass button or a glass rod into which the ends of the wires 12 and

13 are melted and embedded, are connected to each other. The other two ends of the wires

12 and 13 are, preferably by welding, on the end parts 9 and 10 of the lead wires 5 and 6, respectively attached. Appropriately, the thread 4 is through a support wire 15, one end of which in the button

14 embedded and the other end is wrapped around the central part of the thread, additionally supported. The rigid bridge device 12, 13, 14 ensures that the thread 4 and the ends of the lead wires 5 and 6 are held together as a unit freely revolving around or in relation to the exit point of the Wires 5 and 6 from the shaft pressing part 7 can bend.

The wires 5 and 6 are preferably made of a metal or fine alloy with elastic or resilient Properties, for example, an iron-nickel alloy that have approximately equal parts of iron and Contains nickel. The bridge wires 12 and

13 and the support wire 15 can be made of molybdenum.

The structure shown in Fig. 2, in which the reference numbers given in Fig. 1 are used for the corresponding parts, is designed similarly to the structure according to FIG. 1. A difference exists in that an auxiliary strut or an auxiliary bracket 16 is provided is welded with its one end to an intermediate point of the longer lead wire 6 and its other end in one of the shaft pressing part 7 between the lead wires 5 and 6 protruding hollow glass mandrel 17 is loosely anchored. The strut 16 serves to provide a permanent Distortion of the lead wires 5 and 6 under certain conditions in which the wires over their elastic limit can be stressed beyond. So it is z. B. in some In some cases it is desirable to use lead wires 5 and 6 made of nickel. In these cases it can happen that developed by the formation of the press melt 7 heat, the nickel wires at one of the Shaft press part 7 adjacent point are annealed and softened, which in the absence of any the wire strut 16 would result in permanent distortion.

The thread structure according to FIG. 3, which is particularly suitable for cases where the structure is automated Machine production is produced, see different from the embodiments described so far insofar as the bridge device by direct continuations and extensions of the lead wires itself is formed.

The conductors 5 and 6 have parts 17 and 18 which are hook-shaped in connection with the corresponding Bends 9 'or 10' extend sideways away from the thread 4 in the same direction, preferably in a plane which is substantially perpendicular to the plane in which the main parts

Claims (4)

of the lead wires 5 and 6 lie. The outermost ends 19 and 20 of the lead wires are then bent towards one another and embedded with their ends located at a distance from one another in a glass button or a glass bead 14. One end of the auxiliary support wire 15 is embedded in the bead 14 and the other end is wound around the central part of the thread 4. It can be seen that the continuations 17, 19, 18 and 20 of the lead wires together with the insulating bead 14 form a bridge through which the ends 9 and 10 of the lead wires are connected to one another, and that these parts also together with the thread 4 a Form a unit that can swing freely around the exit point of the lead wires 5 and 6 from the pressed shaft part. 4 to 10 illustrate as an example a series of process steps for the production and assembly of the structure according to FIG. 3. According to FIG stepping out; then the wires are bent so that they run essentially parallel to either side of the axis of the shaft 3 which coincides with the axis of the piston 1. The next step illustrated in FIG. 5 is that the hooks or hook-shaped bends 9 'and 10' are formed in the two wires 5 and 6. These hooks are equidistant from the free tips or ends of the lead wires 5 and 6; their direction of projection is also the same and lies in planes which are perpendicular to the plane containing the two lead wires 5 and 6. The next process step illustrated in FIG. 6 consists in that the free or outermost ends of the lead wires 5 and 6 are flattened and truncated so that they can be more easily inserted into the glass bead 14 in one of the following process steps and their correct mutual spacing in the finished Construction is guaranteed. However, this process step is not particularly essential and can be omitted if desired. In the next process step (Fig. 7) the free ends 17 and 18 of the lead wires are bent upwards so that they form continuations of the hooks 9 'and 10' and both in the same directions perpendicular to the plane of the original parallel parts of the lead wires Levels run. The method step illustrated in FIG. 8 consists in that the lead wires are bent backwards (or above) the hooks 9 'and 10' at points so that the parts 9 and 10 directed against the shaft axis are formed and the hooks are in a coaxial position Shaft axis are brought. In this way, the free ends 17 and 18 of the lead wires 5 and 6 are also brought approximately into a plane which runs through the shaft and piston axis and is perpendicular to the plane containing the original parallel parts of the lead wires 5 and 6. The thread 4 is then installed in such a way that it is arranged in the shaft axis and inserted with both ends into the hooks 9 'and 10' and then the hooks are clamped together so that they close around the thread ends. Then the free ends 17 and 18 of the lead wires are bent so that they are at a distance from one another with their tips which may be flattened according to FIG. In the next process steps, which are not illustrated in the drawing, the free ends of the lead wires are connected to one another by a glass rod or a glass bead 14 of appropriate length, whereupon, after appropriate reheating, one end of the support wire 15 is inserted into the bead 14. The support wire 15 is then bent so that it is directed approximately towards the center of the thread 4. Finally, the free end of the support wire is wrapped or looped around the thread 4, as illustrated in FIG. PATENT CLAIMS: 1.Electric incandescent lamp with a gas-tight sealed bulb and a double-coiled thread, the longitudinal axis of which essentially coincides with the longitudinal axis of the bulb, and with two elongated, flexible lead wires of different lengths, which are anchored in the bulb base and extend from this in the longitudinal direction on opposite sides of the piston longitudinal axis into the interior of the piston up to the vicinity of the corresponding thread ends and then bent towards the piston longitudinal axis and electrically and mechanically connected to the corresponding thread ends at points in the piston longitudinal axis, characterized in that the bent parts of the supply wires running transversely to the piston longitudinal axis (9,10) at or near their connection points (9 ', 10') to the thread ends via a rigid bridge (12, 13, 14) are connected to one another in an insulating manner, which are essentially perpendicular to the parts of the piston longitudinal direction Lead wires included tend plane, the thread and the bent ends of the lead wires together with the bridge arrangement form a rigid unit (Fig. 1). 2. Electric incandescent lamp according to claim 1, characterized in that the rigid bridge device an insulating intermediate part (14), which the lead wires at points in the Proximity of their connection points (9 ', 10') connects to the thread ends, and that an additional Support wire (15) attached with one end to the insulating part and with its other end End is wrapped around a central part of the thread. 3. Electric light bulb according to claim! or 2, characterized by an additional wire bracket (16), which is fastened with one end approximately in the middle of the longer lead wire (6) and is loosely anchored with its other end to the bulb wall between the supply wires, preferably in one protruding from the pinch foot (7) between the lead wires (5, 6) Hollow shaft (17). 4. Electric incandescent lamp according to claim 1 or 2, characterized in that the thread and bridge assembly joining the respective ends of the lead wires to form a unit is formed by lateral continuations of the lead wires, these continuations initially run in the same general direction away from the thread and then bent towards each other, so that their outermost ends face each other at a distance and that these ends pass through a