EP1465235A2 - Discharge lamp - Google Patents

Abstract

The discharge lamp has a discharge vessel (1) with an ionisable filling enclosed gas-tight in its interior (10), whereby the vessel has at least one sealed end (11) with a current lead-through connected to an electrode (4) protruding into the interior of the vessel and with a section (403) extending into the sealed end. At least the section of the electrode extending into the sealed end is in the form of a braid.

Description

The invention relates to a discharge lamp according to the preamble of the claim 1.

I. State of the art

Such a discharge lamp is for example in the European patent EP 0 858 098 B1. This document describes a high pressure metal halide discharge lamp for vehicle headlights with a discharge vessel Quartz glass, inside of which an ionizable filling is enclosed gas-tight. The discharge vessel has two sealed ends, each with a feedthrough and one electrode each, each with one of the current feedthroughs are connected and which protrude into the interior of the discharge vessel. The section of the electrodes embedded in the quartz glass is in each case of a spiral encased to reduce cracks in the quartz glass.

II. Presentation of the invention

It is the object of the invention to improve a generic discharge lamp Provide electrodes. In particular, in the material of the discharge vessel Cracks caused by the different coefficients of thermal expansion of the discharge vessel material and the electrode material and through adhesion of the electrodes to the discharge vessel material is reduced without additional components such as those mentioned above State of the art listed spirals are used.

This object is achieved according to the invention by the features of patent claim 1 solved. Particularly advantageous embodiments of the invention are in the dependent Claims described.

The discharge lamp according to the invention has a discharge vessel, in the interior thereof an ionizable filling is enclosed in a gastight manner, the discharge vessel has at least one sealed end with a feedthrough, those with a protruding into the interior of the discharge vessel and themselves is connected into the sealed end extending electrode. According to the invention is at least the portion of the electrode extending into the sealed end as a strand, that is, as a bundle or as a braid of several wires. This is the section of the electrode that is not gas-tight, but still very close to the material of the discharge vessel or sealed end of the discharge vessel and enclosed with the current feedthrough connected is. According to the particularly preferred embodiment of the Invention even the entire electrode, with the exception of its ends, is designed as a strand, because an electrode designed as a strand over its entire length is simpler is to be produced as an electrode which is only partially formed as a strand.

Characterized in that at least the aforementioned section of the electrode is designed as a strand is that of the different coefficients of thermal expansion of the discharge vessel material and the electrode material caused mechanical Tensions due to the elasticity of the strand-like electrode section caught and therefore the risk of cracks or cracks in the discharge vessel reduced. It also bears in comparison to the conventional ones Electrode modified surface geometry to reduce the risk of Cracks or tears in the discharge vessel. The invention is particularly advantageous applicable to discharge lamps that have a quartz glass and Have electrodes made of tungsten because quartz glass and tungsten are very different have thermal expansion coefficients.

The invention can be applied particularly advantageously to high-pressure discharge lamps, whose feedthroughs carry a comparatively high current have to. Metal halide high-pressure discharge lamps for are an example of this Vehicle headlights and in particular mercury-free metal halide high-pressure discharge lamps. These high-pressure discharge lamps usually have a quartz glass discharge vessel with sealed ends, the current feedthroughs with molybdenum foil seals. The protruding into the discharge space Electrodes of the lamp usually made of tungsten are connected to the Molybdenum foil seals connected. The mercury-free metal halide high-pressure discharge lamps need extra thick electrodes because they are still one have to carry higher current than the usual metal halide high-pressure discharge lamps for vehicle headlights. That is why these lamps occur above described problem to an even greater extent than with other high-pressure discharge lamps on.

The section of the electrode designed as a strand advantageously consists of several wires that are twisted or interwoven. The wire gauge or the thickness of the individual wires is advantageously chosen so that it over the length of the electrode, that is, stiff over a length of several millimeters and do not bend under their own weight. The degree of twist The wire is chosen so that between the individual wires after twisting the smallest possible space remains and the wires over the length of the Sufficient electrode or over the length of the electrode section designed as a strand are interwoven to ensure a rigid electrode. This Wires are made of an electrically conductive material, preferably tungsten or a tungsten alloy. The aforementioned wires are at least on one End of the electrode section designed as a strand by a welding or Fused together. This end has better welding properties than the individual wires of the electrode. In particular, this end better with a metal foil designed as part of the current feedthrough, preferably molybdenum foil, are welded as the individual wires. Moreover is ensured by the aforementioned measure that each individual Wire of the strand is electrically conductively connected to the leadthrough. According to of the particularly preferred embodiment of the invention extends as Strand formed section over the entire length of the electrode. In this embodiment are also the wires at both ends of the wire Section or at both ends of the electrode by welding or Fused together. These ends have the shape a hill. One end is used for welding to the current feedthrough, while the other end is designed as an electrode head that goes into the interior protrudes into the discharge vessel and on which the discharge arc of the gas discharge attaches. The coupled electrode head offers the discharge arc of the gas discharge a better starting point than the ends of the individual wires.

For a better welded connection between the metal foil of the current feedthrough and to ensure the end of the section of the electrode designed as a strand, can advantageously the end of the section of the electrode designed as a strand be flattened in the connection area with the metal foil.

III. Description of the preferred embodiment

Figur 1

Eine schematische Darstellung eines bevorzugten Ausführungsbeispiels der erfindungsgemäßen Entladungslampe

Figur 2

Eine Draufsicht auf ein abgedichtetes Ende des Entladungsefäßes der in Figur 1 abgebildete Entladungslampe mit der entsprechenden Stromdurchführung und einer Elektrode in schematischer Darstellung

Figur 3

Eine Draufsicht auf einen Abschnitt der in Figur 2 abgebildeten Elektrode

The invention is explained in more detail below on the basis of a preferred exemplary embodiment. Show it:

Figure 1

A schematic representation of a preferred embodiment of the discharge lamp according to the invention

Figure 2

A plan view of a sealed end of the discharge vessel of the discharge lamp shown in Figure 1 with the corresponding current feedthrough and an electrode in a schematic representation

Figure 3

A top view of a portion of the electrode shown in Figure 2

The embodiment of the invention shown in FIG. 1 is concerned is a mercury-free metal halide high-pressure discharge lamp with a electrical power consumption of approx. 35 watts. This high pressure discharge lamp has a discharge vessel 1 made of quartz glass with an interior 10 and two diametrically arranged, sealed ends 11, 12, each having a current feedthrough 2, 3 have. Two diametrically arranged electrodes protrude into the interior 10 4, 5, which are each connected to one of the current bushings 2 and 3 and between which a gas discharge forms during lamp operation. In the interior 10 of the discharge vessel 1 is enclosed with an ionizable filling, which consists of xenon and several metal halides. The discharge vessel 1 is surrounded by an outer bulb 6, which consists of quartz glass with Ultraviolet radiation absorbing dopants is provided. The lamp points also a plastic base 7, which carries the two lamp vessels 1, 6 and is equipped with the electrical connections 8 of the lamp. The current feedthrough 2 of the base end 11 of the discharge vessel 1 is via the current feedback 9 connected to the first electrical connector 8 while the other Power feedthrough 5 with a second electrical connection (not shown) the lamp is connected. In the lamp base 7, the complete control gear can Lamp or parts of the operating device, for example the ignition device, arranged his.

FIG. 2 shows details of the discharge vessel 1 and the current feedthroughs 2 or 3. The sealed ends 11, 12 of the discharge vessel 1 each have one Power bushing 2, 3 on. The current feedthroughs 2, 3 each have a gas-tight seal molybdenum foil 21 or 31 embedded in the respective end 11 or 12. The side of the respective side facing away from the interior 10 of the discharge vessel 1 Molybdenum foil 21 or 31 is welded to a molybdenum wire 22 or 32, which protrudes from the corresponding sealed end 11 or 12. The side of the respective one facing the interior 10 of the discharge vessel 1 Molybdenum foil 21 and 31 is welded to an electrode 4 and 5, respectively protrude into the discharge space 10. Both electrodes 4, 5 are designed as strands. They each consist of eight tungsten wires that are woven together or are twisted. To achieve the purpose of the invention, it would suffice to use only that extending into the sealed end 11 of the discharge vessel 1 403 to form the electrode 4 as a strand.

FIG. 3 shows details of the electrode 4 of the high-pressure discharge lamp described above. The electrode 4 is essentially rod-shaped and has a length of 6.5 mm and a diameter or thickness of 0.35 mm. This electrode 4 consists of eight tungsten wires, each with a diameter or a thickness of 0.1 mm and are twisted or woven together. The two Ends of the electrode 4 are each formed as a tip 401, 402. The peaks 401 and 402 are each by fusing the ends of the wires using a laser emerged. The dome 401 forms that into the interior 10 of the discharge vessel 1 protruding head of the electrode 4, on the discharge arc during lamp operation the gas discharge starts. The other tip 402 of the electrode 4 is welded to the molybdenum foil 21 of the current feedthrough 2.

To produce the electrode 4, eight tungsten wires of the same length are parallel arranged side by side, so that its first end each in a first holder and its second end is fixed in a second bracket. The distance of the two brackets is variable and initially corresponds approximately to the length of the eight tungsten wires. The brackets are designed as circular disks, the holes have that along a concentric to the circular disc axis Circle or arc segment are arranged and in each one End of a tungsten wire is fixed. A first of the two circular disks Mounts are rotatable about their axis and slidable on a rail arranged so that the distance between the two brackets can be varied, while the other, second bracket is fixed and not rotatable. By rotating the first bracket around its circular disc axis, the eight Tungsten wires twisted or woven together. The resulting strand is cut into pieces according to the desired electrode length. In Figure 3 is a schematic representation of a top view of the electrode 4 produced in this way shown. This electrode has a thickness of 0.35 mm. In terms of current carrying capacity is the electrode 4 according to the invention with a conventional solid, Comparable rod-shaped electrode made of tungsten, which has a diameter of 0.28 mm. The eight tungsten wires each describe a helix, which extends from the first end 401 to the second 402 of the electrode 4. Everyone Wire coils approximately the length of the electrode 4 along a helix five to six times around the outer surface of the electrode 4. The slope of the aforementioned Helix is approximately 1.2 mm. The second electrode 5 is identical to the first electrode 4. The degree of twisting and thus the slope of the The aforementioned helical lines are chosen so that the space between the individual tungsten wires of the electrode 4 is as small as possible and the tungsten wires cannot disentangle itself.

The invention is not limited to the exemplary embodiment explained in more detail above. The electrodes can also consist of more or less than eight wires, if, for example, correspondingly thicker or thinner electrodes are required. In addition, the tungsten wires can be made in a different manner than the preferred one Embodiment are interwoven. For example, they can braided together like a braid. It is also possible that the individual wires of the stranded wire are not interwoven or intertwined at all are, but are designed as a bundle, in which only the ends of the wires together connected, for example fused or welded together.

If necessary, can improve the welded connection with the molybdenum foil 21, the tip 402 may be flattened or / and the molybdenum foil 21 or the tip 402 can be provided with a ruthenium layer.

In addition to the electrodes 4, 5, those made of molybdenum may also be used existing power supply wires 22, 32 or just the ones in the sealed Ends 11, 12 extending portion of the power supply wires 22, 32 in a similar manner How the electrodes are designed as a strand.

Claims (8)

Discharge lamp with a discharge vessel (1), in the interior (10) of which an ionizable filling is enclosed in a gas-tight manner, the discharge vessel (1) having at least one sealed end (11) equipped with a current lead-through (2), and the at least one current lead-through (2 ) is connected to an electrode (4) which projects into the interior (10) of the discharge vessel (1) and which has a section (403) extending into the sealed end (11),
characterized in that at least the section (403) of the electrode (4) extending into the sealed end (11) is designed as a strand. Discharge lamp according to claim 1, characterized in that the section designed as a strand extends to the ends (401, 402) of the electrode (4). Discharge lamp according to Claim 1, characterized in that the section (403) of the electrode (4) in the form of a strand consists of a plurality of wires (41 to 48) which are twisted together. Discharge lamp according to claim 3, characterized in that the wires (41 to 48) consist essentially of tungsten or a tungsten alloy. Discharge lamp according to Claim 3, characterized in that the wires (41 to 48) are connected to one another at least at one end (402) of the section (403) designed as a strand by a welded or fused connection. Discharge lamp according to Claim 5, characterized in that the end (402) of the section (403) of the electrode (4) which is in the form of a strand is connected to at least one metal foil (21) which is in the form of a component for the current feedthrough (2). Discharge lamp according to Claim 6, characterized in that the end (402) of the section (403) of the electrode (4) in the connection region with the at least one metal foil (21) is flattened. Discharge lamp according to claim 1, characterized in that the discharge lamp is a metal halide high-pressure discharge lamp with a discharge vessel made of quartz glass.

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