EP1107284A2 - High pressure gas discharge lamp - Google Patents

Abstract

In a high-pressure gas discharge lamp, tungsten electrodes are arranged on two rhenium rods in an electrode chamber, the rhenium rods still reaching into the electrode chamber. <IMAGE>

Description

The invention relates to a high-pressure gas discharge lamp with two tungsten electrodes, which are each arranged on brackets in an electrode chamber and have a diameter have less than 500 µm.

Similar high-pressure gas discharge lamps are described, for example, in WO 98/37570 A1 and WO 98/37571 A1. Two tungsten electrodes protrude from each, each are still surrounded by a tungsten wire, on essentially self-supporting brackets into an electrode chamber. The brackets used in these publications consist of rhenium or contain rhenium, are in one with the term "Floor of the electrode chamber" designated place with the wall of the electrode chamber in contact. At this point the electrode chamber is also sealed. This happens through a metal foil, each connected to a bracket and a lead wire and on which the material forming the electrode chamber is squeezed.

High-pressure gas discharge lamps, in which the Tungsten electrodes have a diameter of less than 500 µm or in which the Piston length, that is the distance between the base points of a electrode chamber Wall, less than 15 mm. In such high pressure gas discharge lamps the electrode chamber seals as well as the electrode chamber bottom on different Positions. The electrode chamber floor is up to several Millimeters from the seals on the metal foil.

It is an object of the present invention, even with high-pressure gas discharge lamps with two Tungsten electrodes, each arranged on brackets in an electrode chamber are and have a diameter below 500 microns, to ensure that such Lamps can be operated with a sufficient lifespan.

As a solution, the invention proposes a generic high-pressure gas discharge lamp in which at least one of the tungsten electrodes is entirely in the electrode chamber is arranged.

It has been found that the life of the electrode arrangements from the holder and tungsten electrode can be significantly improved if the tungsten electrode is arranged entirely in the electrode chamber. Although therefore, since the The actual sealing of the electrode chamber is only behind that of the tungsten electrode removed approach of the bracket is done, the bracket and the tungsten electrode in the essentially free standing between the seal and the electrode chamber floor is arranged, leads a tungsten electrode, which starts from the electrode chamber behind the electrode chamber floor is sufficient for increased wear. This can be Avoid free placement of the tungsten electrode in the electrode chamber.

If the electrode chamber with at least one holder is at a contact point, speaks to an electrode chamber bottom, in contact, however, there is the possibility that there is sufficient convection around the tungsten electrode that lasts a long time Lamp life allowed.

It is particularly advantageous if the sum divided by the electrode spacing from the electrode distance and the distances between the electrode tips and the respective Electrode chamber floors are between 1.6 and 3. Such an arrangement on the one hand ensures an advantageous formation of a temperature gradient on the Electrode arrangement of tungsten electrode and holder as well as sufficient Convection around this electrode arrangement, through which a long lifespan can be guaranteed.

At least one holder preferably has a rhenium jacket or is formed from a rhenium rod. It is advantageous if the rhenium content of the jacket or rod does not drop below 25 percent by weight. Such an arrangement is particularly suitable for high-pressure gas discharge lamps which contain a gas filling consisting essentially of metal oxyhalides during operation. Here, the electrode chamber can comprise, for example, a mixture of NaJ, SnI ₂ , NaBr, TlBr, HgI ₂ and / or WO ₃ . In addition, mercury, oxygen and argon or another noble gas can be provided in the electrode chamber. Here, the oxygen or WO ₃ serves as an oxygen supplier in order to form oxihalides.

The tungsten electrode is preferably welded onto the holder. Such Connection can be reliably provided even in the smallest dimensions. This applies especially in connection with the use of rhenium.

Especially with small lamp dimensions, it is extremely difficult to guarantee that the tungsten electrode is arranged entirely in the electrode chamber. This applies in particular in connection with industrial production and related tolerances. For this reason it is proposed that the Electrode chamber in at least one cutting plane to at least one electrode at least one holder tapers, the taper gradient in the taper direction up to a contact point or an electrode chamber floor, a real one Minimum passes through. Such a configuration of the electrode chamber can in Area of the electrode chamber bottom an artificial extension of the electrode chamber, which points away from the tungsten electrode. By a such an extension can be reliably achieved that the tungsten electrode for Entirely arranged in the electrode chamber.

In practice, this can be ensured by the fact that during the manufacture of the high pressure gas discharge lamp, in which the lamp body is pressed by means of a mold and inside the gas-filled electrode chamber with its on the electrode chamber bottoms electrodes protruding into the electrode chamber is formed after the molding of the lamp body in the area of at least one electrode chamber bottom is subsequently expanded. It goes without saying that there is also a smooth transition between the shaping of the lamp body by pressing and the subsequent Extension can be provided.

The lamp body can be heated in the area of the electrode chamber base to expand it become. This ensures a particularly simple manufacture of the respective Lamp.

It goes without saying that a real minimum continuous taper gradient or one such a procedure also independent of the other features of the high-pressure gas discharge lamp, especially advantageous regardless of the type of electrodes Can be used to be reliable, especially under conditions series production, provide sufficient free electrodes even with small lamps to be able to. In particular, lamps whose bulb length can be provided in this way is shorter than the inner wall chamber or as the sum of the electrode spacing and the distances between the electrode tip and the respective electrode chamber bottoms.

Figur 1

eine erfindungsgemäße Hochdruckgasentladungslampe in schematischem Schnitt, wobei die Schnittebene senkrecht zu der Dichtebene liegt und

Figur 2

eine vergrößerte Darstellung der Lampe nach Figur 1 in einem Schnitt senkrecht zu der Schnittebene in Figur 1.

Further objectives, advantages and properties of the present invention are explained on the basis of the description of the following drawings, in which a high-pressure gas discharge lamp according to the invention is shown as an example. Show it

Figure 1

a high-pressure gas discharge lamp according to the invention in a schematic section, the section plane being perpendicular to the sealing plane and

Figure 2

2 shows an enlarged illustration of the lamp according to FIG. 1 in a section perpendicular to the section plane in FIG. 1.

The high-pressure gas discharge lamp shown in the figures has a sealed one Glass body 1 made of quartz glass. However, this can also consist, for example, of mono- or polycrystalline ceramics exist. Here, a wall 2 encloses a shape pressed quartz glass an electrode chamber 3, which with a suitable mixture filled with xenon and mercury as well as various salts. The electrode chamber 3 is sealed at the level of metal foils 4, which 5 electrically with corresponding leads are conductively connected.

Electrode arrangements 6 protrude from the metal foils 4 into the electrode chamber 3 inside. The electrode arrangements 6 consist of a tungsten electrode 7a and one Bracket 7b. The holder 7b is a rhenium rod, on which at a transition point 7c the tungsten electrode 7a is welded on. As can be seen directly from FIG. 2, the tungsten electrode 7a is arranged entirely in the electrode chamber 3. Opposite, the holder 7b is electrical at one point 4a with the film 4 conductively connected.

The holders 7b enter the electrode chamber 3 at a contact point 8a. This Place is usually referred to with the term "electrode chamber floor". A bead-like recess closes immediately at the electrode chamber bottom 8a 8b before the actual electrode chamber 3 begins. As from Figure 2 can be seen, the electrode chamber 3 thus tapers from the tungsten electrode 7a proceeding to the holder 7b, the taper gradient in the taper direction passes through a real minimum precisely at the recess 8b. Since in the present embodiment the electrode chamber 3 even expands again at this point, is in this area the taper gradient is even negative.

As can be seen immediately, the inner wall chamber is in the present exemplary embodiment (BWK), which is the sum of the electrode distance (EA) and the distances (PBA) between the electrode tips and the respective electrode chamber bottoms, greater than the bulb length (KL) of the lamp.

In the present exemplary embodiment, the electrode spacing is approximately 4 mm and the distance between an electrode tip and the respective electrode chamber floor about 1.3 mm. It follows that the sum divided by the electrode spacing from the electrode distance and the distances between the electrode tips and the respective Electrode bottoms is 1.65.

It is understood that such an arrangement, in which the inner wall chamber is greater than the piston length and / or an arrangement in which a degree of taper a real minimum also passes through independently of the other characteristics such high pressure gas discharge lamp is advantageous and a new dimension in Freedom of design opened when designing such lamps.

Claims (10)

High-pressure gas discharge lamp with two tungsten electrodes (7a), which are each arranged on brackets (7b) in an electrode chamber (3) and have a diameter of less than 500 μm,
characterized,
that at least one tungsten electrode (7a) is arranged entirely in the electrode chamber (3). High-pressure gas discharge lamp according to claim 1,
characterized,
that the electrode chamber (3) is in contact with at least one holder (7b) at a contact point (8a). High-pressure gas discharge lamp according to claim 2,
characterized,
that the sum of the electrode distance (EA) and the distance (PBA) between the electrode tips and the respective electrode chamber floors (8a) divided by the electrode distance (EA) is between 1.6 and 3. High-pressure gas discharge lamp according to one of claims 1 to 3,
characterized,
that at least one holder (7b) has a rhenium jacket. High-pressure gas discharge lamp according to one of claims 1 to 4,
characterized,
that at least one holder (7b) has a rhenium rod. High-pressure gas discharge lamp according to one of claims 1 to 5,
characterized,
that the tungsten electrode (7a) is welded onto the holder (7b). High-pressure gas discharge lamp according to one of claims 1 to 6,
characterized,
that the electrode chamber (3) tapers in at least one sectional plane to at least one electrode or to at least one holder (7b), the tapering gradient passing through a real minimum in the tapering direction up to a contact point. High-pressure gas discharge lamp according to one of claims 1 to 7, characterized by a piston with a piston length (KL) which surrounds an electrode chamber (3), in each of which an electrode arrangement is arranged on an electrode chamber base (8a) (7a, 7b) protrudes, the piston length (KL) being smaller than the sum Electrode distance (EA) and the distances (PBA) between the electrode tips and the respective electrode chamber bottoms (8a). Method for producing a high-pressure gas discharge lamp, in which a lamp body (2) is pressed by means of a mold and a gas-filled electrode chamber (3) is formed on the inside with electrodes (7a, 7b) protruding into the electrode chamber (3) at electrode chamber bottoms (8a),
characterized,
that after shaping the lamp body (2), it is subsequently expanded in the area of at least one electrode chamber base (8a). Manufacturing method according to claim 9,
characterized,
that the lamp body (2) is heated to expand in the area of the electrode chamber base (8a).

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