EP0477735B1 - High pressure discharge lamp - Google Patents

Description

The invention relates to a high-pressure discharge lamp with the features mentioned in the preamble of the main claim.

Such high-pressure discharge lamps filled with inert gas have relatively high operating currents; this requires relatively large and therefore heavy electrodes - generally made of high-melting tungsten - and even with lamps of medium power (some 100 W) rod-shaped power supplies, "electrode rods", of a few mm in diameter. The electrode rods, also made of tungsten, are melted through the piston wall in a gas-tight manner using complex, predominantly manual processes using intermediate glasses, the thermal expansion coefficient of which lies between that of the tungsten and the very small expansion coefficient of the quartz glass.

The melts or bushings are mechanically very sensitive; No forces may be transferred to them through the electrode rods, since they can easily be damaged by cracks and thus leak.

DE-GM 19 39 204 shows a noble gas high-pressure lamp in which the bulb necks are narrowed like a capillary from the transition into the bulb up to the point of melting.

The constriction is achieved by deforming the piston neck, which has been heated to approx. 2000 ° C with the oxyhydrogen gas blower and then softened; Vacuum in the bulb makes it easier for the quartz glass to fall onto the electrode rods; When cooling to room temperature, an annular gap of a few tenths of a mm is created between the electrode rod and the support capillary.
The capillary provides secure support for the electrode rods and a transfer of forces, such as occur during handling and transport due to vibrations of the heavy electrodes, onto the melting point is practically impossible.

From DE-GM 78 35 279 a high-pressure discharge lamp with a shortened support capillary in the part of the piston neck near the piston is known.

The shortening of the capillary leads to an increase in the mechanical stability of the lamp, because the shortening reduces the risk of capillary rupture, it facilitates the evacuation of the lamp, because the pump resistance is reduced due to the now shorter annular gap, and it leads to the loss of part the complex deformation work to be carried out manually by special forces on the piston neck, significant cost advantages.

From DE-PS 30 29 824 a high-pressure discharge lamp and a method for its production are known, in which each bulb neck has only a slight constriction near the transition to the bulb, against which a loose on the electrode rod pushed-on support element, for example in the form of a circular cylindrical roller made of quartz glass which is only a few mm long, is resiliently pressed by a tungsten spiral spring which is also loosely pushed onto the electrode rod between the support element and the melt. With this type of electrode rod support, the advantages already described for the shortened capillary come to the fore:
Due to the slight narrowing of the piston neck, there is practically no risk of breakage in this area, the pumping path along the supporting element is reduced to a few mm, the complex deformation work is reduced to a minimum - slight indentation of the piston neck.

A disadvantage of the designs according to DE-PS 30 29 824 and DE-GM 78 35 279 for electrode rod support, however, is that a relatively large volume to be filled with inert gas is created in the piston-distant space of the piston neck between the melting point and the rod support. The noble gas in this volume remains relatively cold during lamp operation, since it is not heated directly by the discharge processes, and leads to a lowering of the temperature and thus the operating pressure of the noble gas in the actual discharge bulb via convection.
In order to achieve the operating values of lamps with an unshortened capillary, it is therefore necessary to significantly increase the cold filling pressure of the noble gas in lamps in the version according to DE-PS 30 29 824 and DE-GM 78 35 279, which in turn increases the essential for the lamp ignition Breakdown voltage undesirably increases and it also increases additional costs due to the larger filling quantity of the expensive noble gas (eg xenon!).

In lamps in the version according to DE-PS 30 29 824 also occasionally occur in unfavorable cases - especially due to resonance effects during transport - large forces between the support element and the inner wall of the bulb neck, which cause abrasion and injury to the quartz glass surface with a number of disadvantageous consequences for the correct lamp operation.

Another disadvantage of the designs according to DE-PS 30 29 824 and DE-GM 78 35 279 for supporting the electrode rods is that the convection currents that occur can lead to a reduction in the stability of the discharge arc.

From EP-PS 00 86 479 an embodiment of the electrode rod support is now known which avoids the disadvantage of the relatively large volume to be filled with inert gas in the part of the piston neck remote from the piston. A long circular cylindrical roller, for example made of quartz glass, is used as the support element, which - loosely pushed onto the electrode rod - fills the entire piston neck between the melting point and the actual piston; a tungsten coil spring, also loosely pushed between the electrode and the roller, is used to position the roller.
However, this solution has not proven itself in practice, since a coordination between the length tolerances that occur and the spring force for the safe positioning of the relatively heavy support element could not be guaranteed sufficiently reliably, and this caused damage to the melting caused by a support element movable in the axial direction of the electrode rod.

The present invention is based on the object to find reliable support for the electrode rods without complex deformation work on the piston neck and with the smallest possible volume to be filled with inert gas in the piston neck.

This object is achieved according to the invention by the characterizing features of claim 1.

Particularly advantageous refinements can be found in the subclaims.

Based on the tried and tested design of the electrode rod support according to DE-PS 30 29 824, the volume to be filled with inert gas in the piston neck is reduced by the fact that one or more circular cylindrical disks, preferably made of ceramic, have a diameter slightly below the inside diameter of the piston neck , between a support element preferably made of quartz glass and a spiral spring made of tungsten, which is supported against part of the melt, are loosely pushed onto the electrode rod. The construction according to the invention requires only a small amount of deformation work on the piston neck in order to produce the constriction necessary for the positioning of the support element and allows simple coordination between the production steps which result from manually carried out production steps Length tolerances and the force caused by compression of the coil spring, so that as a result a resiliently firm fit of the support element and disc (s) on the electrode rod can be achieved without problems.

The central bore of the disks is selected to be slightly larger than the electrode rod diameter, so that any radial displacement of the disks with respect to the central axis of the electrode rod is possible up to (one-sided) contact with the inner wall of the piston neck. The disks thus take over part of the support function, since they contribute to the damping of electrode rod vibrations via the friction against one another or with the support element, and thereby advantageously relieve the actual support element, so that in the embodiment according to the invention there are no signs of wear and tear due to transport stresses on the support element and / or occur on the inside of the piston neck.

In addition, the disks advantageously cool the electrode rod by dissipating heat as a result of heat conduction from the electrode rod into the quartz glass wall of the piston neck. The temperatures on the electrode rod are significantly reduced by the discs pushed onto it; as a result, the melting of the electrode rod and the base region are thermally relieved, as a result of which the lamp operational safety is increased. In order to improve the heat dissipation of the piston neck which is additionally heated thereby, the outer surface of the piston neck is increased from the transition into the piston to in to increase the radiation provide the area under the base sleeve with a layer of high radiation emissivity in the infrared and / or visible wavelength range.

Another advantage results from the fact that the thermal expansion coefficient of the aluminum oxide preferably used for the panes with 7.5x10⁻⁶ / K is more than a power of ten greater than that of quartz glass with 0.56x10⁻⁶ / K. The lamp gap between the disks and the bulb neck is therefore noticeably smaller than at room temperature during lamp operation, which hinders the convection currents which impair the arc stability, while a larger ring gap facilitates the evacuation of the discharge vessel during manufacture.

The invention is explained below using an exemplary embodiment.

The figure shows an embodiment in side view, partially in section.

In the piston 1 made of quartz glass with two piston necks 2, 2 '- also made of quartz glass - are two electrodes 3, 3' diametrically opposite. The electrodes 3, 3 'are mounted on rod-shaped current leads made of tungsten, the electrode rods 4, 4'. The electrode rods 4, 4 'are melted in a gas-tight manner at the ends of the piston necks remote from the piston and are electrically conductively connected via strands with base sleeves 5, 5' cemented onto the piston necks. Each of the electrode rods 4, 4 'is supported by a support element 6, 6' of quartz glass loosely pushed onto it, which is loosely supported by a between the relevant melt 7 the respective electrode rod 4, 4 'pushed, compressed coil spring 8 made of tungsten via also loosely pushed onto the respective electrode rod 4, 4' discs 9, 9 'made of alumina ceramic resilient against a constriction 10, 10' in the piston neck 2, 2 'at the transition to Piston 1 is pressed.

The inside diameter of the piston neck is 19.0 + 0.4 mm, the outside diameter of the discs 18.8 - 0.05 mm, their thickness 5.0 ± 0.1 mm.

The diameter of the inner bore of the discs is 4.3 + 0.05 mm, the electrode rod diameter 4.0 ± 0.02 mm.

The discharge vessel is filled with xenon of approx. 8 bar, the nominal power consumption of the lamp is 2 kW.

Each of the piston necks 2, 2 'is provided on its outer surface from the transition into the piston to the area under the base sleeve 5, 5' with a high-temperature-resistant black layer 11 '.

The high-temperature resistant black layer contains Fe₂O₃ pigments and leads to a reduction in temperature from 250 ° C to 220 ° C at the outer ends of the bulb necks when the lamp is operated at nominal power in a horizontal burning position.

Claims (5)

1. High-pressure discharge lamp comprising a quartz glass bulb (1) which is filled with inert gas, has two bulb necks (2, 2′), and in which there are diametrically opposed two electrodes (3, 3′) which are mounted on rod-shaped supply leads, the electrode rods (4, 4′), which are led outwards in a hermetically sealed fashion in the part of the respective bulb neck (2, 2′) remote from the bulb, and are supported in the vicinity of the transition of the respective bulb neck (2, 2′) into the bulb (1) by a support element (6, 6′) which is pushed loosely onto the electrode rod (4, 4′) and is pressed resiliently against a constriction (10, 10′) in the respective bulb neck (2, 2′) by the force of a compressed spiral spring (8) which is likewise pushed loosely onto the electrode rod between the support element (6, 6′) and the melt seal (7), characterized in that one or more discs (9, 9′), preferably made from ceramic, are pushed loosely onto the electrode rod (4, 4′) between the respective support element (6, 6′) and the spiral spring (8).
2. High-pressure discharge lamp according to Claim 1, characterized in that the bulb necks (2, 2′) are provided on their outside with a high-temperature resistant coating (11′) of high emissivity in the infrared and/or visible spectral region.
3. High-pressure discharge lamp according to Claim 1, characterized in that the discs (9, 9′) pushed loosely onto the electrode rod (4,4′) between the support element (6, 6′) and spiral spring (8) have a thickness of between 1 to 5 mm and a diameter which is between 0.2 to 0.8 mm below the inside diameter of the bulb neck (2, 2′).
4. High-pressure discharge lamp according to Claim 1, characterized in that the pushed-on discs (9, 9′) comprise aluminium oxide ceramic.
5. High-pressure discharge lamp according to Claim 2, characterized in that the high-temperature resistant coating (11′) comprises a high-temperature resistant black lacquer.

Images