DE1589184A1 - Electric lamp and process for its manufacture - Google Patents

Description

General Electric Company, 1 River Road, Schenectady, N.Y., USA Electric lamp and process for its manufacture

The invention relates to improved electric lamps and similar devices with filament, particularly on arrangements in which a very thin filament goes straight through the ends of a quartz bulb is melted through. This melting is achieved by carefully observing the wire diameter, the wire temperature and the quartz temperature during the Melting and the conditions of the ambient air in which the melting takes place, allows. That way you get an intimate bond of the quartz with the filament in the form of a tight closure that does not have any cracks or hairline cracks during or after operation of the lamp at temperatures up to a maximum of 1000 ° C has, or calibrates loose *

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For a long time the incandescent lamp was the normal source of lighting, especially for use at low power, but with good color rendering. Unfortunately, the theoretical and practical maximum efficiency of a GlUhbape are relatively low because the radiation of a filament black body radiation is practically! And only a small fraction of the radiation within the visible spectrum, while the largest T _e il is given of the radiation in the form of heat. However, the incandescent lamp was able to hold its own against other lighting sources in the low-voltage consumer group because of its relatively small dimensions and its low cost. Efforts to improve the efficiency of incandescent lamps have continued, however. As an example of the currently commercially available filament lamps with currently the best efficiency, the Larapen manufactured by General Electric Company, DSA and sold as "quartz line incandescent lamps" according to DAS 1 246 874 may be mentioned.

In general, such "quartz line lamps" have a thin cylindrical tube made of quartz with a relatively long, too the tube concentrically arranged tungsten filament, whose Diameter makes up a considerable part of the inner diameter of the quartz tube, so that the inner wall of the quartz tube is operated at a relatively high temperature. Deterioration of the hot tungsten filament is made with by the presence of iodine low partial pressure in a protective gas in the quartz tube. This iodine ensures at the operating temperature of the filament

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an iodine regeneration cycle, the deposition of tungsten from Filament on the inner walls of the lamp bulb «prevented. Such Ewei Kachteiles deposit has once it sets the permeability of the walls, and on the other hand it leads to the consumption of the Tungsten filament. The Jcd regeneration cycle causes the tungsten on the lamp walls again with the iodine to form a tungsten-iodine compound connected, which migrates to the hot filament and is decomposed there, with the tungsten being deposited again on the filament will.

Although the lamps mentioned above are among the lamps with the highest efficiency and longest service life count as they are currently available, even though they compete with other lighting systems can lead to the measures required to achieve high efficiency and long service life of such lamps Manufacturing costs that are undesirable from an economic point of view are. The high manufacturing costs arise from the costly double welding of the filament with one Hoiybdän foil, which is then fused with the quartz. aside from that must have a strong and durable conductor on the other end of the molybdenum foil be welded on. So making these lamps requires four welds and the use of fragile molybdenum foil. In addition, an excessive amount of quartz is required for such lamps, which is also uneconomical.

009814/0992 ORIGINAL INSPECTED

Sin object of the invention is thus to provide lamps with high efficiency au having a simple, economical and effective means * hermetically to melt by the Sndwände of the quartz tube at the filament, on mechanically stable manner, so that no jumps in operating conditions or Hairline cracks arise.

According to the invention, in the case of incandescent lamps with a quartz or quartz-like bulb and a heat-resistant filament, the filament is melted directly into the wall of the lamp bulb without any intermediate part. Filament can be readily melted directly into the quartz lamp envelope by making the filament thinner than 40 mils (1.016 mm), degassing it before and during the meltdown to eliminate the presence of gas adsorbed on the filament, and filament and quartz during the meltdown is constantly flushed to prevent molecular or gaseous impurities emitted from the filament or quartz during heating from becoming trapped in the fusion joint between these two parts .

In the following the invention will be described in more detail with reference to the drawings.

Figure 1 is a section through an incandescent lamp according to the invention.

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Figure 2 is a section through an alternative training to the Incandescent lamp according to Figure 1. I.

Figure 3 is a section through another alternative construction. the incandescent lamp according to the figure, 1.

<I.

Since quartz was used for lamp bulbs, attempts have been made by various methods to feed the filament through the Melt down the quartz bulb. Since the coefficient of expansion of quartz differs from that of most metals and in particular that of the highly heat-resistant metals differs significantly, considerable difficulties arose, in particular in cases where the Schmelzstell® is exposed to high temperatures will. As already mentioned, the best incandescent lamps currently available are designed in such a way that the quartz, finally, of the part carrying the melted leads is exposed to a temperature during normal operation which is considerably above room temperature. Because of this, the difference leads in the Coefficient of thermal expansion, if it is not somehow compensated for or otherwise avoided, leads to deterioration the fusion by dissolving the metal from the quartz, if the fusion bond is subjected to large temperature changes, so that the airtight connection between the filament and the quartz is not lost. Because of the fragility of most filaments you have never tried to eic the filament directly into the quartz bulb.

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to melt. Instead, it has hitherto generally been assumed that an intermediate piece leading the current through the quartz, which is connected on the one hand to the filament and on the other hand to the supply line, to be melted into the quartz bulb. As mentioned above, this is an expensive, complicated and inexpedient solution, since it requires four welds and an intermediate piece, since the intermediate piece of various shapes is generally difficult to handle and is quite expensive. According to an already known proposal, a holder made of heat-resistant material with a flattened edge is used to create the seal, and the filament is welded to the flattened end of the supply line. at Another attempt to solve the problem of different thermal expansion, one or more components are provided, one section of which is very small in one transverse direction but very large in the other transverse direction, for example a section of wire which is flattened on a ribbon; included the overall cross-section is retained, but at least one dimension is very small. In another known proposal the melting takes place by means of a thin intermediate piece, which is melted into a quartz tube and provided with connections at the ends of the leads. In another case, the problem of different thermal expansion was advocated So solve that a tungsten conductor was provided with a coating and melted in a Quan & eil. To solve a similar one Problem of different thermal expansion was in another

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Fall an intermediate piece, a thin one, into a fine one Glass tubes containing melted tungsten wire for the Installation in a hermetically sealed glass vessel intended. To do this, you have a thin tungsten wire in a cylindrical one Glass tube arranged and the glass tube to a vacuum pump connected. While the vacuum pump then reduces the pressure in the glass tube, certain parts of the tube are heated, so that they collapse around the wire and seal one Form a degree. One of the ends of the molten part of the glass is then cut off, leaving a part made of one consists of a thin piece of glass into which a fine tungsten wire is hermetically sealed. This glass part can then be used as a closure for glass vessels for various applications.

According to the invention, these extremely complicated and expensive known methods are avoided in a simple manner by that the filament is melted directly into the quartz bulb in such a way that a strong, heat-resistant seal is created, which is at operating temperatures of, for example, up to 1000 ° C neither deteriorates nor detaches from the wire.

Figure 1 shows an embodiment according to the invention, at which an airtight piston 1 has a hollow cylindrical part 2 with two closed tubular ends 3. The filament 4 is arranged concentrically to the axis of the piston 1.

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assigns and continues without interruption, or Äfosöiiluß du ^ ch ά ± ® tubular ends S therethrough.

As shown in Figure 1, listens DI® coil of the filament and the filament ^ mimmt the shape © ines straight wire as soon as it leaves the piston first This design is not necessary, however, and the filament can also be designed when leaving the bulb 1 as it is within the cylindrical part 2 of the bulb 1, or as a straight wire, as is inclined in FIG. Although the filament, according to FIG. 1 “fetus” consists of a single wire which is arranged in a helical manner in its central part, it can also be designed as desired, provided that the starting wire from which the filament is made is named below Abraesstmgsbedinguagen corresponds.
I.

It has been found that a firm, effective connection can be created between a tungsten filament and a quartz bulb if the starting wire for the filament has a diameter of less than

UZ has less than 40 mil. (1,016 km) if the wire length before and during the

-> melting is made incandescent, so that possibly adsorptive

Can escape ^ Bierte gases, and when means are provided to prevent (0 to all made by him during the Erhitssens of the filament to remove substances to u ^ that Zn from the quartz dispensed material prior to or during the filament travels u®s meltdown and it contaminated. The filament 4 may be made ir-

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009814/0992

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important * well, as already mentioned, an essential © task of the Purge gas © ® dariii Itasföirfc "the tungsten filament against Veruareinigimgea afosusch & nBSSBsdie during the sale at the Schmalz « K ßea Qii & rs are released.

Weian Quars is heated to its softening point, so that © r expected to shrink around the Wolframgltihfaden and it melts.,!, For example, at 1750 to 2200 ° C _s is the quartz steam farei, water vapor in the presence of a hot Wclfram ~ fadesas can have a harmful cycle ec ^ icb, in which the WasseiaaolisMil © migrate to the tungsten, are broken down there and form tungsten oxide and a tungsten compound * which removes to the quartz back wall © rt uad ffolfram u-on the filament. Bjßser Syklus 1st for? Folfraaiglüfefäd®ö very sehädli. ^ Mad therefore ®m extremely important that does not pass on heating the quartz zurEildung the Einsehraelsstelle liberated from the quartz steam to the tungsten filament. This can be achieved by passing gas between the quartz and the filament at high speed, even when the purge gas is under low pressure (e.g. mercury column). The same goal can also be achieved with lower split velocities or even if the velocity of the gas between the quartz and the tungsten is practically zero for a short time, for example shortly before the final meltdown in a closed system, there is no other opening through which the purge gas can be passed. In this case it is.

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BATH ORIGINAL

it s <sfor desirable that © in very high pressure @ iK @ S: inactive. Gas or noble gas of high molecular weight »for example argon or? Krypton is present in such a way that the mean length of the path of the water molecules is very kissable in comparison with the figure. . It was composed of quartz and tungsten.

As an example of the relationship between pressure and distance, which satisfies this mean free path requirement, it should be mentioned that with a 0.502 ram of wire in a 1.016 mm quartz tube Inside diameter a pressure of the rinse or of the intermediate of raised gas, even if not purged, of approximately 10 mm 'of mercury is sufficient. With this disorder results a mean free path of the water molecule of approx 0.127 miss, so it is highly unlikely that any Water molecule reaches the tungsten filament.

In view of the above, it is readily apparent that it is not expedient or advisable to sell _c seals swischeis dom tungsten and Qm & zz according to this € »m or another process and replace an iriiactive gas atmosphere with a rough vacuum related areas is often regarded as equivalent. If a vacuum is created between the filament and the quartz in the £ on @ and the quars sum softening is heated, the middle © Wegläng «» -

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.the water vapor emerging from the quartz is extremely large, and it is very likely that the water will run down the Wolfrauaglühfaden reached and a water cycle is created, which leads to the deposition of the Lists tungsten oxide layer on the Wolfraiagglowfad. Ss would be therefore It makes no sense to evacuate when such melting points are formed the zone between the tungsten and the quartz during the melting process to consider.

In the manufacture of lamps of the invention one uses expediently with a quartz tube after Figure 1 of the drawing an outside diameter of approx. 10 mm and an inside diameter of approx. 8 mm with two "constricted" end sections, the outer diameter of which approx. 8 mm and the inner diameter is approx. 2 mm. It is advisable to unthread the son © and rchm © 3ssr Section at least one of the ends of the quartz tube to be designed so large that it corresponds to the outer diameter of the filament of the filament can accommodate. Because the filament is only inserted at one end too warden, this requirement only applies to the end, through that the. Filament inserted v / ird.

It is also useful to have the quartz tube in the middle with a To provide ventilation tubes through which the wide melting point used purge gas Strumen can after the first melting point has already been completed, and this also serves to evacuate the space inside the lamp envelope or for example to fill with iodine of low pressure or about

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Desired £ all3 to increase the pressure of the filling gas or even out reduce. After the two ends of the lamp bulb have been melted in place have been closed and all other Steps have been taken with the aid of this vent tube, the vent tube is closed and ea What remains is a nipple or pump nozzle that completes the hermetic seal of the lamp envelope. It should be noted here

fc. -

ψ notes that this vent tube and the remaining nipple correspond to only one embodiment of the invention and that lamps according to the invention can also be manufactured without this tube.

When using a tube lana, the lamp according to FIG. 1 can be produced in the following manner. As already stated above, the quartz tube has an expediently converted or doubly converted, spirally arranged filament with or without straightened ends. For the sake of simplicity, however, it is assumed that the filament, as shown in FIG. 1 , has straightened ends - The filament is inserted through the large opening end portion 3 and the straightened end θ of the filament is caused to exit through the other end portion 3 of the envelope. The quartz bulb is then inserted into a honing device and, for example, an argon beam with a pressure of, for example, 10 mm of mercury, is directed into the opening in one band section 3 in order to flush the entire interior of the lamp bulb with argon. By a suction device

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"the Spillgaastroa and the low snueppressure-upright- ·· -. A bit of gas is achieved by putting outside ata Lara-ραΏ & οϊΙϊβΒ θ: Ιώθκ Breianes ¹ on od @ sr the quays in a different way, ■ in such a way that calibrate the temperature of the filament to © inen

Value increased between 1750 and 2200 ° C. At temperatures below 1750 ° C, the degassing and the removal of gas particles adsorbed on the surface is insufficient and the production of good oil-melting points is difficult. On the other hand, at T © mpöratui ^o © a over 2200 ° C the effects on the quars calves are such that their rigidity is lost. It was found that it was necessary both with regard to the best possible degassing of the Wolfraaiobsrf 2.äcii © n and iia with regard to di · ?; 'Preservation of the rigidity of the psyche piikolbsiis during the ¥ © rschra © l: sens ata'güuststen' is that the warming through the buttocks raises the filament to © ine 1! @ Temperature

1800 and 2600 ⁰ C. When the filament has reached this temperature, which is measured with an optical pyrometer, the quartz is heated more strongly, for example by a second jet of strongly heated gas flowing around it, at ~ Sv. For example, by means of a nozzle arranged on the circumference or by means of an ine-around section. 3 logged ring-shaped resistance ta & ösfasisu & g, or by a plasma torch or a focused® Las © rh®issung. In hot tea, the temperature of the quartz is raised to over 2200 ° C and the quartz falls around the tungsten filament and forms a hermetic part with it.

BAD ORiGlNAU 0098U / 0992

A constricting force can also be used so that the quartz collapses around the filament and creates a shock induction with it. Such a force can be exerted, for example, by a differential pressure of, for example, several pounds per square inch (several hundred Torr) by pumping the purge gas out of the quartz bulb through the aforementioned nipple 5 so that the pressure within the bulb is somewhat reduced . lower than the pressure outside the piston. Instead, you can the end 3 can also be mechanically squeezed together by means of a suitable device. After one end of the KoBsns 1 with the meltdown Connection has been provided, the process is repeated at the other end, with the heated gas now through the Endabscfanitt S is inserted with the smaller opening and through the tube flows out in the middle of the bulb so that the lamp bulb can be completely flushed through. After the quartz of the second end section has collapsed around the tungsten filament and a hermetic seal has been created, the tube becomes in the middle of the piston melted, namely after the piston after Has filled the tube with gas or changed the gas pressure at will, and it remains the nipple 5. This is the production the incandescent lamp ended "

According to another embodiment of the invention, it becomes practical . the same procedure as described above is used, only no tube is provided in the center of the lamp envelope, and the

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;. ; " __ - 17 -. · ■■■■■■ .. ■. ■ ■

-Second fused-in part is at higher inert gas pressure, at «* for example approx. 1 atmosphere, created. In doing so, the high causes. Pressure of the inert molecules in the vicinity of the filament and the one with The quartz to be fused together reduces the mean free path of the water developed by the quartz and thus prevents the formation of a water cycle and the deposition of tungsten oxide on the tungsten filament.

In the description of the manufacture of lamps according to the invention it was indicated that Inextgasg for flushing the quartz tube and for heating the tungsten wire are preferred. Nevertheless, in the manufacture of lamps according to the invention, -. low pressure air can be used for these purposes. In such a case, if the air pressure is low? enough is, for example, 10 to 100 mm of mercury, very little Oxide on <?, © r Ob ^ s'fi & §he of the tungsten filament. Even if see yourself low * amount of oxide, for example a single layer, is the solubility of tungsten oxide in quartz such that a very small amount of oxide adsorbs into the quartz as soon as it comes into contact with it, so that there is intimate contact between the quartz and the metallic tungsten of the filament comes about, which facilitates the formation of good melt-in points according to the invention.

The above-described, improved incandescent lamps with Highly heat-resistant, metallic filaments can simply,

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easily and at low cost, using a metal filament of highly refractory material having a metal wire diameter of no more than 40 mils (1.016 mm) directly, with no interposed spacer or any welds thereto, is melted directly through the quartz bulb wall. This fusion connection is achieved by heating the heat-resistant Incandescent filament from 1750 to 2200 ° C and rinsing with hot Gas to remove contaminants, or optionally in the presence a gas under high pressure, so that impurities, . which have developed from the tungsten or the quartz, do not deposit on the tungsten and form undesirable deposits on it.

Sine lamp of the invention was Q25 inch (6.35 ram) outside diameter and 0.15 inch (3.81 RAM) inside diameter made of a quartz tube of 3 inch (76.2 mm) in length, that in the middle of the longitudinal side of a Entluftungsröhrchen 0.1 inch (2.54 mm) outside diameter. A 20 mil (0.508 mm) diameter tungsten wire was formed into a 0.05 inch (1.27 mm) diameter and 1 inch (25.4 mm) long helical coil that was positioned along the longitudinal axis of the quartz tube and extended extended over the entire length of the pipe. One end of the tube was closed with an O-ring and an end clamp; the other end of the tube was temporarily connected to a container in which there was dry nitrogen at 10 mm mercury pressure. A mechanical backing pump was connected to the venting tube and sucked in the stick

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Λ.

material through one end of the quartz bulb at a flow rate equivalent to 1 cc per second under normal temperature and pressure conditions. With the aid of two oxyhydrogen gas burners, the quartz flask was heated so slowly at a distance of about 1 inch (2 1/2 cm) from its end that the tungsten wire was ^{heated to 1800 °} C. before the quartz was deformed. This was achieved with a 2 minute heating cycle. After heating for 2 minutes, the softened quartz was brought into contact with the tungsten wire by the differential pressure and the melting point was thus formed. This process was repeated to make the second melt point, but with the nitrogen source connected to the other end of the quartz bulb. The vent tube was then heated until it softened and completely sealed off. The lamp produced in this way is shown in FIG.

FIG. 2 shows another embodiment according to the invention, in which the incandescent thread 4 runs concentrically through the piston 1 and is melted directly into the piston at points 7 and 7. The protruding from the sealing-7 end 8 of the filament 4 enters a ¹ »hollow, tapered opening in the tapered tubular portion 3 of the piston 1 a, which terminates with an inwardly tapered body that surrounds the point at which the end of the filament 8 emerges from the melting point 7. The entire, tapering opening 9 around the exit point is filled with a solidified mass 10 made of metal or a metal alloy, which is connected to the end section 8 of the filament 4

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mechanically and electrically firmly connected .. In addition, is a. · Lamp lead 11 embedded in the metallic mass 10 in order to connect the lamp to a power source electrically and mechanically in order to operate the lamp. The solidified metal mass 10 completely fills the inner end of the tapering opening 9 in the tubular part 3 of the piston 1 during its manufacture if it is present as a liquid in the opening 9. Since the mass is 10 | solidifies and contracts on cooling, it loosens somewhat in every direction, namely by a few angstrom units, from the inner wall of the opening 9. Although this detachment means that there is no longer a hermetic seal between the metal filling compound, e.g. nickel, and the quartz this peeling is not so significant that it affects the mechanical stability; The lead Ii to the electrode therefore carries the lamp securely, and no mechanical loads whatsoever are transmitted to the end section 8 of the filament 4. A similar metallic cup 10 is filled into the opposite opening in the tapered section 3 ° of the piston 1 at the other end and a similar electrode lead 11 is embedded therein. The metallic mass 10 consists of a metal or a metal alloy, the melting point of which is between approx. 600 and 1500.degree. If the melting point is below 600 ⁰ C, the mass 10 can be too soft at the operating temperature of the lamp, for the end of the lamp, this temperature can almost reach, although the filament itself may have a temperature of, for example 1000 ° C. When the melting point of the metallic mass 10 is above approx. 1500 ° C

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is, the silica metterial of the piston can undesirably in the melting of the metal or metal alloy that the Form mass 10, softened or deformed. Pie metallic mass 10 can consist of nickel, lead, tin or a solder or an alloy of lead, tin or nickel, their melting point within the mentioned temperature range lies. '

The nickel mass 10 not only provides a good mechanical and electrical connection between the end portion 8 of the filament and the lamp lead 11 and not only frees the end section 8 from any mechanical stresses that result from it the holder of the lamp through the lead 11 ergeten * but it fulfills an additional, very important task. Sa the end portion 8 of the filament 4 is outside of the quartz bulb and is heated by the same current that the parts of the filament embedded in the quartz and those in the hollow lamp bulb 1 Enclosed parts heated to the extent that they are glowing and give off light and heat, such the end portion 8 tends to be very getting hot. If such a temperature rise of the end section 8 was allowed, the end section 8 would soon reach that point oxidize so that it would be destroyed. The parts of the filament enclosed within the quartz bulb 1 and its hollow part are protected against oxidation by the enclosure. The end connector 8, on the other hand, is not protected against oxidation.

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Since it is not shielded from the ambient air, you had to keep away from excessively high temperatures associated with the glow, to avoid destruction through oxidation. The resistance that the end section 8 offers to the electric current and its Temperature, so must the temperature of Hasse 10. increase from nickel, which is in intimate thermal contact with him. Therefore, the mass 10 is an excellent heat sink, which avoids the end portion 8 of the filament 4 from being so high is heated 'that it is oxidized and then destroyed.

FIG. 3 shows another exemplary embodiment of that in FIG. 1 invention shown. In FIG. 3, the same parts are provided with the same reference numbers. The piston 1 «is tubular

Section 2 and two end sections 3 and 3 "on, through. - a

concentrically arranged in the lamp envelope

Filament 4 at a small distance from the inner walls of the bulb

passes through. The incandescent filament 4 is ^{hermetically passed through the quartz forming the bulb 1 at 7 and 7 r} , and an end section 8 of the filament 4 extends outside the hermetic seal into a tapered opening in the quartz bulb.The opening has a mass 10 of elemental nickel filled, which is in intimate mechanical and electrical contact with the end section 8 and completely fills the volume of the end opening 9. A cup-shaped metallic end piece 12 surrounds the end of the quartz bulb 1 and is connected to the nickel compound 10, for example by welding, soldering or suitable mechanical means, in order to create an intimate mechanical, electrical

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to form thermal and thermal contact. For "electrical connection of the lamp, the electrodes 12, which are provided on the opposite end" of the bulb 1, become contacts tied together.

In the manufacture of the electric lamps shown in FIGS. 2 and 3, the zones 7 and 7 * are manufactured as shown in FIG Connection with the lamp according to FIG. 1 has been described. After the filament has been melted down at both ends of the black bulb, the lamp bulb is preferably held vertically and a pointed nickel rod is inserted into the opening at the top 9, where the end 8 of the filament emerges from the quartz of the fusion point 7. A protective gas atmosphere, which preferably consists of hydrogen or nitrogen, is applied to the Exit point of the filament end 8 directed, and this point is heated so that although the nickel melts, but that the quartz does not become so soft that either the properties of the quartz-Wolf ram amalgamation or the formation of the zone where the end occurs of the filament protrudes from the Schaelzstelle 7 of the piston 1,

is affected. Used molten nickel, and the heat _source: has thus far been filled Nachdea the opening 0 that a sufficient mechanical, electrical · and thermal connection exists with the end portion 8 of the filament, the lamp supply line 11 equal to each other serves as a support, in the overall is , which can consist of superheated gas or an electrical resistance coil, is removed so that the mass 10 can solidify. To example-

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one opening (0.15 inches) 3.81 ram in diameter To fill, 1 to 5 g of nickel are used. After the nickel has solidified, the lamp is turned over and the same procedure is followed applied to the other end of the lamp. This completes the creation of the fused connection,

After the meltdowns have been completed, an additional

of the filament end 8 Protection against possible destruction / by ingress of air into the The gap between the Nickel · mass® 10 and the tube made of quartz or the quartz-like material is only a few Angstrom units obtained by pouring a thermoplastic resin into this gap. This thermoplastic resin is enough to fill the gap keep free of air and still maintain at operating temperatures its airtightness and its strength.

Although the improvements according to the invention for "quartz line incandescent lamps" with iodine »or halogen regeneration cycle are particularly important are, the invention can be used in the production of broadly outlined lamp envelopes made of quartz and quartz-like material and is not applicable to lamp envelopes with a special one Gas filling limited. In the same way is the invention, though For the sake of simplicity, it is described in connection with lamp bulbs made of pure quartz, applicable to other translucent, vitreous, predominantly silica-containing material, for example on Vycor (98% 810), which is mainly made of Hsselde

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and has a similar, low coefficient of thermal expansion, which allows the implementation of the electrical Metal leads bring difficulties of the size mentioned above with calibration, but which can be overcome according to the principle of the present invention.

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Claims (14)

speech 1. Electric oil lamp with sealed quartz glass bulb and with a filament made of highly heat-resistant material arranged in the bulb, characterized in that the filament (4) has a diameter of 5 and 40 mils (0.127 mm and 1.016 mm) and that with it (4) out one piece of existing ends (β; 8) passing through the piston (1) directly into compressed end sections (3, 3 ° Figure 1; 3/7, 3 »/ 7 · Figures 2 and 3) of the lamp bulb (1) are hermetically sealed. 2. Electric incandescent lamp according to Anspsi ch l _t, characterized in that the lamp bulb (1) has the shape of an elongated, cylindrical tube and that the filament (4) is designed as an axial, coiled spiral. 3. Electric incandescent lamp according to claim 1 or 2, characterized characterized in that that by the consumable parts passed wire end (8) is surrounded by a metal mass (10) covering the passage point. 4. Electric incandescent lamp according to claim 1 to 3, characterized in that the compressed Sndabechnitt (3/7; 3 · fr ·) of the lamp bulb «(1) over the through the Hermetically sealed melting point (7.7 ») protruding through 0098U / 0992 End (8) of the filament wire (4) extending out and around it, and a metallic ¹ connector (10) of larger cross-section than the filament wire (4) electrically connected to the end (8) of the wire (4) and into the narrowed end section (3.3 ») of the piston (1) is firmly embedded, but without being hermetically fused therein (Figure ^ 2 and 3). ι. 5. Electric incandescent lamp according to one of claims 1 to 4, characterized in that the metallic connection part (10) contains an electrical lead, the one with the protruding end (S) of the glow wire (4) electrically connected and in the compressed lamp bulb end © (3.3 °) is embedded. 6. Electric incandescent lamp according to one of claims 3 to 5, characterized in that the metallic connecting part (10) is a solidified metal mass which a good connection with the protruding end of the tungsten wire represents and in the narrowed section of the lamp bulb bene is embedded. 7. Electric incandescent lamp according to one of claims 3 to 6, characterized in that the metallic connecting part (IQ) holds an electrical lead (11) ent which is connected to the metal mass . 0098U / 0992 ~ 28 ~ 8. Electric incandescent lamp according to one of claims 3 to 7, characterized in that the metal tub (10) is arranged in a tapered opening (9) whose inwardly directed tip is at the point where the Wolfraiadraht (4) emerges from the hermetically sealed Melting point (7) emerges. 9. Electric incandescent lamp according to one of claims S to 8, characterized in that the metal mass (10) consists of metal or a metal alloy and that its softening temperature is above the operating temperature of the lamp bulb (1) and its melting point is below the softening point of the lamp bulb ^ (1) and preferably consists of nickel, lead, tin or alloys thereof having a melting point between 600 ° C and ISOO ⁰ C. 10. A method for producing an electric incandescent lamp, characterized in that a Filament (4) made of heat-resistant wire from 5-40 UiI (0.127 to 1.016 mm) diameter in a bulb (2) made of quartz glass xaLrd, with a filament end (6; 8) through a narrowed zone of an open end of the lamp bulb emerges that the filament in an inert gas atmosphere to 1750.degree is heated to 2200 ° C for degassing the filament surface, and that the end (3; 7) of the lamp bulb above its softening temperature is heated and hermetically fused with part of the filament end, while the high temperature of the filament is maintained. 11. Ancestors according to claim 10, characterized that the filament is heated by a stream of inert gas at a pressure of more than 10 mm of mercury is heated. 12. The method according to claim 10 odei ¹ 11, characterized in that metallic material (10) held in a cavity (9) in the open Eude of the lamp envelope It surrounds the end of the filament (4) which protrudes from the hermetically sealed seal (7) so that the end of the lamp bulb is heated to such a temperature that the essential material melts and the filament end inside of the piston end is embedded in the mimicked mass, and that the molten material in contact with the filament end is caused to solidify. 13. The method according to one of Claims 10 to 12, thereby characterized in that furthermore a feed line (11) into the molten. Metal mass is embedded before it solidifies. 14. av ^ 'en. according to one of claims 10 to 13 characterized by filling out the between there solidified metal mass (10) and the end surrounding it of the quartz bulb (1), the Hanrapaltes kit is a thermal material. 0098H / 0992 Blank page