NL7908413A - ELECTRIC LAMP. - Google Patents

Description

PHN 9633 1 • "Electric lamp"

The invention relates to an electric lamp with a quartz glass lamp vessel, which is provided with power supply wires, which run to an electric element arranged inside the lamp vessel, which are guided through the wall of the lamp vessel in a vacuum-tight manner and which have a coating around a part of their length of intermediate glass, between which ends the wall of the lamp vessel is fused with said coating. Such a lamp is known from British Patent Specification 710,434.

Lamps that have a high operating temperature are often made with a quartz glass lamp vessel, which is understood to mean glasses with a SiO 2 content of at least 95% by weight, and with current supply conductors of tungsten or molybdenum. These glasses have a thermal expansion coefficient (about 7 x 10 K ~), which differs significantly from that of tungsten (45 × 10 K) —7 -1 and molybdenum (54 × 10 ~ K ~). Because of these large differences in thermal expansion coefficient, it is generally common to design the current supply conductors in the place where they are vacuum-sealed in the wall of the lamp vessel as a thin foil to which an internal and an external current supply conductor are welded. However, during the production of the welded joints and also when the conductors are melted into the wall of the lamp vessel, failure occurs as a result of breakage of the foil. Furthermore, the welded connections must always be checked for soundness, the whole of the current supply conductor is slack due to the presence of the foil, so that it is difficult to mount the internal current conductor properly positioned in the lamp vessel and the foil limits the permissible amperage through the power supply conductor. Notwithstanding these drawbacks of the construction outlined, practically all types of 790 84 13 PHN 9633 2 #, / ¾ quartz glass lamp bulb lamps commercially available are nevertheless provided with this construction. Only in lamps with a high current intensity, such as short arc discharge lamps, in practice a melted wire is forced to be used as a current supply conductor. This shows that there are economic and technological barriers to using fused wires as current supply conductors for other lamp types.

According to the said British patent specification 10 710,434, a vacuum-tight fusion of the power supply wire into the wall of the quartz glass lamp vessel is obtained by providing the power supply wire at the area of the fusion in the wall of the lamp vessel with a fused coating of an intermediate glass or a number of intermediate glasses and the wall of the lamp vessel to fuse therewith between the ends of said coating.

However, it is particularly difficult and time consuming to achieve a good fusion of the wall of the lamp vessel with the coating of the power supply wire. The quartz glass of the lamp vessel to be formed must be incident on the coating of the current supply wire. Although this can be accelerated by pressing the quartz glass all the way against the glass cladding with tools, this process is also difficult to mechanize.

On the other hand, it has been found that if a pinch seal is produced around the glass cladding, as is customary with lamps using a thin metal foil to realize a vacuum-tight closure of the lamp vessel thereon, no reliable sealing is obtained and frequent bursting occurs. ·

The object of the invention is to provide electric lamps with a quartz glass lamp vessel provided with current supply wires, which lamps have a robust construction which is easy to realize and which does not imply any practical limitations with regard to the diameter of the current supply wires.

This object is with lamps of the 7908413 *? The type referred to in the above-mentioned type has been realized in that the lamp vessel has at least one flat pinch seal, in which at least one current supply wire is included, which pinch seal on each of its two larger side surfaces 5 for each current supply wire included in the pinch seal is over its respective wire has the entire squeezed length extending, raised back.

It has been established experimentally that this lamp has a reliable construction and is easy to manufacture in a mechanized process, even if current supply wires of 0.6, 0.8 mm diameter or more are used. In contrast, lamps with the larger side surfaces of the nip seal were not provided with such a raised back, in many cases even when cooling immediately after the nip seal has been made, it will show a jump.

The invention is based on the following insight. Intermediate glasses are generally understood by those skilled in the art to have glasses with a thermal expansion coefficient lying between the expansion coefficients of the materials to be joined, in this case metal of the power supply wire and quartz glass of the lamp vessel. Since quartz glasses, due to their high SiO2 content, have a very low coefficient of expansion and also a very high softening point, the intermediate glasses must have a lower SiO2 content to achieve a higher coefficient of expansion and at the same time have a lower softening temperature. .

When making a flat pinch seal, the intermediate glass has a temperature that is only slightly different from the temperature of the quartz glass.

As a result, the intermediate glass has a relatively low viscosity. The pressure exerted by the squeeze blocks and transferred to the intermediate glass by the quartz glass makes the intermediate glass flow smoothly, resulting in the coating of the power supply wire - when making a conventional pinch seal, the larger side surfaces not having a high back, such as lamps according to the invention which have been anticipated - will be damaged or even partially disappears 7908413% by weight of PHN 9633. In the finished pinch seal, the current supply wire is then no longer surrounded all round by transition glass, which creates stresses in the quartz glass which lead to a jump.

By providing the surface of the squeeze blocks with a trench, the position of which is matched to the position of the current supply wire in the still open end of the lamp vessel to be formed, surfaces are squeezed inside the squeeze seal when squeezing between the assembled quartz glass. as it were, a cavity is cut out for the power supply wire and its intermediate glass cover.

As always with the deformation of glass, it is also important here that the glasses are allowed to flow and fuse with each other, so that glass surfaces are prevented from enclosing sharp corners at the location where they meet. Depending on the manner in which the sealing process is carried out, it may therefore be recommended to reheat the pinch seal.

It is of particular importance that the lamps according to the invention not only can be manufactured easily and also mechanically, have a very reliable construction and enable high currents with low resistance losses, but also that the construction offers the possibility of several power supply wires in have a pinch seal. This is of course impossible in the construction known from the British patent cited, since the fusion of the current supply wire is rotationally symmetrical there.

In case the lamp according to the invention is a discharge lamp, for instance a high-pressure mercury vapor discharge lamp, and the electrical element arranged inside the lamp vessel is an electrode pair, in addition to the current supply wire to a (main) electrode, a current supply wire to an auxiliary electrode are included. If the lamp according to the invention has an incandescent body as an electrical element, the lamp can, depending on its intended use, be designed as a two-pin 790 84 13 PHN 9633 5 or as a single-pin lamp.

It has been found that very good results are obtained with intermediate glasses having an expansion coefficient (oC) 5 in the range of about 11 to 17 x 10 K "1 over the temperature range of 30-800 ° C.

Examples of such glasses (composition in weight percent) are shown in the following table.

10 j I .. - - - - j Si02 B203 A12 ° 3 Ca0 o (x 10 'K-1 yes 86.9 9.0 4.1 11 | b 86.4 9.6 4.0 13 15; C j 81.9 I 13.1 j 4.5 0.5 15 | d 81.0 f 10.9 I 7.1 1.0 17 j | _ 2Q The intermediate glasses can be conventionally connected to the tungsten or molyb power supply wires -they are melted to form a coating thereon, for example, if the glass is assumed to be of rod-shaped glass, it can be spread on the wire in a flame.

If the glass is available in a tubular shape, it can be slid over the wire and subsequently fused to the wire by, for example, inductive heating.

In lamps where a vacuum-tight seal is realized on a foil contained in a pinch seal, the pinch seal is only vacuum-sealed over a part of the length of the foil, which lies between the ends of the internal and external welded to the foil. current conductor. In order to mechanically anchor these internal and external current conductors in the pinch seal, the length of that pinch seal must be significantly greater than the length of the vacuum-tight portion.

7908413 PHN 9633 6

In the case of lamps according to the invention, however, the pinch seal is vacuum-tight over the entire pinched length of the current supply wire. This opens up the possibility of giving lamps according to the invention significantly shorter pinch seals, which not only entails a saving in quartz glass, but also a smaller lamp. This means that luminaires of a smaller size and lower weight can also be used.

Embodiments of lamps according to the invention are shown in the drawing. In it is

Fig. 1 is a longitudinal section through a high-pressure mercury vapor discharge lamp,

Fig. 2 a section through the lamp of FIG. 1 along the line II-II, FIG. 3 a side view of a single-pin halogen filament lamp,

Fig. K is a cross-section through the pinch seal of the lamp of Fig. 3 along the line IY-IY,

Fig. 5 a side view of a two-pin halogen bulb,

Fig. 6 is a section through the lamp of FIG. 5 taken on the line VI-VI.

In Fig. 1, a quartz glass lamp vessel 1 has flat pinch seals 2 and 3 · A pinch wire 2 is fed with a current supply wire h, around which wire 4 the pinch seal 2 has the same geometry as the pinch seal 3 flows around the wire. 5 · Power supply wire 5 has a part of its length all around a transition glass coating 6 having the composition b from the preceding table fused to the wire 5. The quartz glass of the pinch seal 3 is fused therewith between the ends of the coating 6. The power supply wire 5, which is made of tungsten and has a diameter of 800 µm, carries tungsten wire windings at its end 7 to thus form a main electrode. In addition to wire 5, a tungsten wire 10 provided with a coating 9 of the same intermediate glass is pinched, the end 11 of which forms an auxiliary electrode, 7908413 PHN 9633 7

In figure 2 the shape of the flat nip sealing 3 is clearly visible. The pinch seal 3 has smaller side surfaces 12 and 13 and larger side surfaces 14 and 15. On the latter, there is a raised back 16 and 5, respectively, each located above the power supply wire 5 and its covering 6 and along its entire squeezed length expired. Likewise, raised ridges 18 and 19, respectively, are present above the power supply wire 10 and its coating 9, 10. In Figure 3, molybdenum power supply wires 32 and 33 of 600 µm diameter, respectively, are received in the flat pinch seal 30 of the quartz glass lamp vessel 31. The wires have a coating of intermediate glass 34 and 35 respectively, with the composition 15 d from the table. The power supply wires 32 and 33 carry a tungsten filament 46.

It can be seen from Figure 4 that above each of the current supply wires 32 and 33, respectively, incorporated in the flat pinch seal 30, there are raised ridges 38, 39, 40 and 41 respectively on the larger side surfaces 20 and 37 of the pinch seal. These extend over the entire pinched length of the power supply wires 32 and 33. The lamp shown can be used for projection purposes.

In Figure 5, the quartz glass lamp vessel 50 has a flat pinch seal 51 and 52 of mutually equal geometry. Pinched seal 52 incorporates a 700 µm diameter tungsten current supply wire 53 to which a coating 54 of composition a) of the Table is fused. Between the ends of coating 54, the glass of the pinch seal 52 is fused therewith. At its end located within the lamp vessel 50, the power supply wire has some tungsten wire windings 55 screwed into the filament 56. The lamp can be used as a flood-light lamp.

Figure 6 shows the elevated ridges 59 and 60 present above the power supply wire 53 and its sheath 54 on the respective larger side surfaces 57 and 58 of the pinch seal 52, extending along the entire pinched length of the power supply wire 53 expired.

10 15 20 25 30 35 7908413

Claims (3)

1. An electric lamp with a quartz glass lamp vessel which is provided with power supply wires, which run to an electric element 5 arranged inside the lamp vessel, which are guided vacuum-tightly through the wall of the lamp vessel and which have a cover of intermediate glass around a part of their length, between which ends the wall of the lamp envelope is fused with said coating, characterized in that the lamp envelope has at least one flat pinch seal, in which at least one current supply wire is included, which pinch seal on each of its two larger side surfaces for each in the nip seal included power supply wire has an elevated back extending above the respective wire along its entire pinched length. Electric lamp according to claim 1, characterized in that at least two power supply wires are included in a pinch seal. Electric lamp according to claim 1 or 2, 20, characterized in that the intermediate glass has an expansion coefficient -7 -1 in the range of 11 to 17 10 K in the temperature range of 30-800 ° C. 25 30 790 84 13 35