WO2009068099A1 - Discharge lamp and method for producing a discharge lamp - Google Patents

Abstract

The invention relates to a discharge lamp (1) and a method for producing a discharge lamp, wherein a resin layer (38, 40) is present between a piston shaft (6, 8) of a discharge vessel (2) and a base (10, 12) placed thereon.

Description

 Confession

Discharge lamp and method for producing a discharge lamp

Technical area

The invention relates to a discharge vessel according to the preamble of claim 1 and a method for producing a discharge lamp according to the preamble of claim 6.

State of the art

Such a discharge lamp can be designed, for example, as a high-pressure discharge lamp, as described on the Internet domain www. OSRAM. de is described. Such high-pressure discharge lamps are used for example in projection systems and headlamps. With regard to the basic structure of such lamps is beispielswei ^¬ se to WO 2006/099850 A2 or DE 10 2005 030 113 Al refers.

Accordingly, high pressure discharge lamps have a round or oval in cross-section discharge vessel - also called piston - of quartz glass, in the interior of which two other spaced zuein ^¬ electrodes are formed. At the discharge vessel diametrically two piston shafts are formed, in each of which an electrode holder is contacted with egg ^¬ ner power supply. In each case a base sleeve is placed on the end portions of the two piston shafts, which in turn is contacted with the associated Stromzu ^{¬ management} . In the aforementioned discharge lamp types, the interior of the discharge vessel is filled with high-purity xenon, mercury or metal halides, such as iodine, bromine. To transfer the initially non-conductive gas or vapor into a conductive plasma state, the discharge must first be ignited. For this purpose, due to the ionization of the gas or the vapor always present charge carriers are accelerated in an electric field; These generate a charge carrier ^avalanche by impact ionization, which finally becomes the output of a conductive plasma channel. Suitable ballasts ensure that the current is limited by the discharge to permissible values. In stationä ^¬ ren conductive plasma is electrically neutral to the outside, there are ions, electrons, neutral ^¬ particles in the ground state and the excited state adjacent. The mobile electrons absorb energy in the applied electric field and transmit it by impact on the atoms or molecules of the discharge. This results in both elastic shocks, in which only kinetic energy is exchanged, and in inelastic collisions, ie, for the excitation or ionization of atoms or molecules. Upon return to the ground state, the energy released then is emitted as radiation characteristic of the atom or molecule in question.

In conventional high-pressure discharge lamps, the connection between the respective piston skirt and the base sleeve takes place via graphite strip, which is wound in several layers around the piston skirt in order to fill the annular space between the base sleeve and piston skirt. slotted base sleeve is resiliently pressed onto the piston skirt.

The problem with such a socket is that it may come due to variations in the thickness of the graphite strip to a different contact pressure of the base sleeve to the piston skirt, so that it during operation of the lamp and with a corresponding thermal load to damage the lamp and thus to a Failure can come.

Presentation of the invention

The object of the present invention is to provide a Ent ^¬ discharge lamp and a method for their preparation, in which the operational reliability is improved.

This object is achieved according to the invention in terms of Ent ^¬ charge lamp by the features of claim 1 and in terms of the method for producing a discharge lamp by the features of claim 6. Particularly advantageous embodiments of the invention are described in the appended claims.

The discharge lamp according to the invention has a discharge vessel filled with a filling gas, in which two electrodes are accommodated and to which at least one piston shaft is attached, which is connected to a base which is contacted with a current supply of an electrode.

Between the base and the piston shaft, a connecting material is introduced, which is designed according to the invention as a thermosetting resin. In the method according to the invention for producing such a discharge lamp, the resin is accordingly introduced between the piston skirt and the base and then cured.

By using such a resin instead of the conventional graphite tape winding, the socket can be done much easier and largely automated, the dosage of the resin is done automatically, ^{beispielswei ¬} se via a dosing. Due to the high viscosity in the non-exclusive cured resin is ensured that a flat connection between the base and piston ^¬ shaft made un the clearance between the piston shaft and socket is filled, so that a gleichmä ^¬ ssige conditioning of the base is ensured and the risk of Lamp failure due to excessive thermal stresses in this area compared to the conventional solution described above is significantly reduced.

The resin is preferably designed to discolor or degrade upon reaching a predetermined excess temperature at which damage to the discharge lamp is to be feared, such that the color change or the typical odor resulting from outgassing is an indicator of lamp overheating. That is, the resin of the invention performs a dual function, because it acts on the one hand as a connecting means between the base and piston skirt. Secondly, it fulfills a safe ^¬ integral function by changing modes when exceeding a maximum temperature, the color and / or outgas. In one embodiment of the invention, an epoxy resin is used.

The discharge lamp is preferably designed as a double-sided high-pressure xenon high-pressure discharge lamp.

The curing can be done for example by inductive heating ^¬ men.

Short description of the drawing

The invention will be explained in more detail below with reference to a preferred embodiment.

The sole FIGURE shows a longitudinal section through a xenon high-pressure discharge lamp.

Preferred embodiment of the invention

The invention is explained below with reference to the example ei ^¬ ner xenon high-pressure discharge lamp 1. Such lamps contain no mercury and are therefore particularly environmentally friendly. However, the invention is not limited to xenon lamps but also applicable to other types of lamps, for example in mercury-containing lamps. Xenon high pressure discharge lamps have a significantly longer life and produce a light that is very similar to daylight. Such discharge lamps are therefore preferably used in projectors, stage headlights and vehicle headlights.

A so-called "burner" of the discharge lamp 1 has a discharge vessel 2 made of quartz glass, with an interior space 4 and two diametrically arranged, sealed piston rings. Shafts 6, 8, on whose end portions in each case a So ^¬ ckelhülse 10, 12 is placed. This does not have to be resilient, as in the prior art. In the interior 4 protrude two coaxially formed, opposing electrodes 14, 16, between which forms a gas ^¬ discharge during lamp operation. In the discharge vessel 2, an ionizable filling is included, which consists of high-purity xenon in the xenon high-pressure discharge lamps.

The electrodes 14, 16 are each designed as a two-part electrode system consisting of current-carrying, rod-shaped electrode holding bars 18, 20 and electrode heads 22, 24 soldered thereto. According to the figure of the lower electrode head 24 is to produce high tem- peratures designed as a cone-shaped head cathode to ensure ei ^¬ NEN defined arc approach and a sufficient flow of electrons due to thermal emission and field emission. The upper illustration in the electrode head 22 is designed as a thermally highly loadable, clay nenförmige head anode, wherein the radiating ^¬ power pastung by adequate dimensioning or loading, preferably Wolframbepastung, the electrode surface is improved. In order to suppress or at least significantly reduce negative gas reactions for the luminous flux and the life behavior of the discharge lamp 1, a non-illustrated getter can be arranged inside the discharge vessel.

The electrode holding bars 18, 20 are for holding the

Electrodes by rod fusion with transition glasses (not shown) to the respective piston shaft 6, 8, wherein in each case an end portion 26, 28 of the Electrode holding rod 18, 20 protrudes frontally from the zugeord ^¬ Neten piston shaft 6, 8 and contacted with the attached base sleeve 10, 12. The construction of such transition glasses and possibly further connection means between electrode holding rod and piston skirt is known from the prior art, so that further explanations are unnecessary.

Instead of the Elektrodenstabeinschmelzung can also be used in each case a molybdenum plate, which is melted to avoid stress in the respective piston shaft 6, 8 and on the one hand with a Elektro ^{¬ the} holding rod 18, 20 and on the other hand welded to a Stromzu ^{¬ management} .

The respective end section 26, 28 projecting from the ends of the piston shafts 6, 8 is inserted in each case into a plug contact 30, 32 of the base sleeve 10, 12 and optionally soldered thereto. The inner circumference of the socket sleeves 10, 12 is executed with excess with respect to the outer periphery of the associated piston shafts 6, 8, wherein in the remaining annular space 34, 36 between the base sleeve 10, 12 and the piston shaft 6, 8 epoxy resin 38, 40 is ^{¬ introduced} , Is ensured This introduction can occur for example with ^¬ means of a metering device which meters a sufficient amount of epoxy resin 38, 40, so that a flächi- ge, high-strength connection between the base sleeves 10, 12 and the piston shafts 6. 8 The ^{curing of} the epoxy resin can be accelerated by inductive heating. In principle, ande ^¬ re curable resins may be used instead of an epoxy resin having a rea ^¬ sponding temperature resistance.

This resin is designed so that it outgases when a predetermined excess temperature range in which damage to the discharge lamp 1 may occur, whereby the vapors resulting from the outgassing are perceived due to their typical odor, so that the overheating is pointed out. Additionally or alternatively, the resin is designed such that it changes color in this over-temperature range, this discoloration is then also perceived as an indicator of rewriting ^¬ th an allowable temperature. Suitable measures can then be taken in good time, for example switching off the lamp or improving the cooling in order to avoid damaging the lamp.

The invention has been based on a XBO discharge lamp he explained ^¬. In principle, however, this invention can also be used in other discharge lamps.

Disclosed are a discharge lamp and a method for producing a discharge lamp, wherein a resin layer is provided between a piston shaft of a discharge vessel and a pedestal mounted thereon.

Claims

claims 1. Discharge lamp with a filled with filling gas Ent ^¬ discharge vessel (2) in which two electrodes (14, 16) positioned ^¬ taken and are formed on the at least one plunger shaft (6, 8) (with a socket 10, 12 ) is connected, in turn, to a power supply (18, 20) of the electrode (14, 16), wherein between Thus ^¬ ckel (10, 12) and piston shaft (6, 8) is a Wireless Manager ^¬ TERIAL (38, 40) is introduced, characterized in that the connecting material is a curable resin (38, 40). 2. Discharge lamp according to claim 1, wherein the resin (38, 40) is designed such that it discolored or outgassed upon reaching a predetermined excess temperature range. 3. Discharge lamp according to claim 2, wherein the overtemperature range between 19O ⁰ C and 26O ⁰ C. 4. Discharge lamp according to one of the preceding claims, wherein the resin is an epoxy resin (38, 40). 5. Discharge lamp according to one of the preceding claims, wherein this is a capped on both sides Xe ^¬ non high-pressure discharge lamp and each base (10, 12) via the resin (38, 40) with the respective piston shaft (6, 8) is connected. 6. A method for producing a discharge lamp (1) with a filling vessel filled with filling gas (2), in which two electrodes (14, 16) are accommodated and to the at least one piston shaft (6, 8) is attached, which is connected to a base (10, 12), which is contacted with a power supply of an electrode (14, 16), wherein between the base (10, 12) and piston skirt (6, 8) a connection material made of resin (38, 40) is introduced. 7. The method according to claim 7, wherein the resin (38, 40) is cured by inductive heating. 8. The method according to claim 7 or 8, wherein the resin (38, 40) is metered during introduction by means of a metering device.