WO2008119697A1 - High-pressure discharge lamp - Google Patents

Abstract

The high-pressure discharge lamp comprises a ceramic discharge vessel (2) having a capillary at the end. An electrode system (16) is inserted in the capillary (6), the system comprising a head, a shaft and a passage. The capillary comprises a constriction (20, 21, 22), which has a reduced inside diameter. Said design reduces the variation of the color temperature.

Description

Title: High pressure discharge lamp

Technical area

The invention is based on a high-pressure discharge lamp according to the preamble of claim 1. Such high-pressure discharge lamps are in particular equipped with a ceramic discharge vessel.

State of the art

EP-A 1294011 discloses a high-pressure discharge lamp in which an electrode system is inserted into the capillary of a ceramic discharge vessel. Typically, the inner diameter of the capillary is constant.

A similar high pressure discharge lamp is shown in EP 1 211 714. Here, in order to avoid a variation of the color temperature, the capillary is designed such that it is designed in one piece with the discharge vessel and has a defined radius of curvature at the edge between capillary and internal volume. However, such a construction is relatively expensive and does not sufficiently reduce the variation of the color temperature.

Presentation of the invention

The object of the present invention is to prevent a depletion of the filling in the discharge vessel and to improve the stability of the color temperature over the life of a high-pressure discharge lamp.

This object is achieved by the characterizing features of claim 1. Particularly advantageous embodiments can be found in the dependent claims.

Basically, in this initial situation, the problem arises that the capillary is not separated from the discharge vessel. The filling in the discharge vessel can withdraw into the free spaces between the electrode system and the inner wall of the capillary, the so-called dead volume. The result is then a depletion of the filling and on the other a kind of distillation effect, which changes the filling in the discharge volume. This leads to instability and change in as well as drift of the color temperature during operation and over the life. Therefore, one usually tries to minimize or eliminate the dead volume as much as possible from the outset. For example, this is done with the aid of a glass solder, which is resistant to high temperatures, see WO 2005/124823. An alternative is a slipped-on Mo coil as shown in EP-A 1294011.

According to the invention, the ceramic discharge vessel has a capillary with a given inner diameter. The capillary can be made integral with the discharge vessel or even be an independent component. However, the inner diameter of the capillary is not kept constant as usual, but over a certain length Lr, in particular 0.5 to 3 mm, on the discharge volume facing part of the capillary so reduced that the inner diameter DA here so far narrows that it is approximately is equal to the diameter DE of the electrode head. The electrode system is divided into head, shaft and bushing. The diameter DF of the implementation is greater than the smallest diameter DA of the bottleneck. There- with the bottleneck also provides a stop for the implementation.

The structure should be such that upon insertion of the electrode system into the capillary, the electrode head together with the shaft passes through the constriction and the remaining part abuts against the constriction.

By means of the shaft length Ls and the length of the constriction Lr, the electrode spacing can thus also be set.

The bottleneck can assume various geometric shapes. Depending on the type of geometry, the electrode, in particular the head, must be adapted accordingly.

The constriction may be an integral part of the capillary. However, it is also possible to use them as a separate part in the capillary.

Thus, the constriction at the transition to the discharge volume acts as a kind of closure of the capillary and separates the capillary from the actual discharge vessel. This creep the filling during operation in the capillary is much more reliably prevented than previously known measures. This is particularly evident when several components are used in a metal halide filling.

This system is also well suited for metal halide fillings that do not use mercury completely or almost completely. Brief description of the drawings

In the following, the invention will be explained in more detail with reference to several embodiments. The figures show:

Figure 1 is a ceramic discharge vessel in section; FIG. 2 shows a detail of the end region;

FIG. 3 shows an alternative embodiment of the end region; Figure 4 shows another alternative for the end.

Preferred embodiment of the invention

An embodiment of a metal halide high-pressure discharge lamp 1 is shown in FIG. 1. It has a ceramic discharge vessel 2, which is closed on both sides. It is elongated and has two ends 3 with seals 6. Inside the discharge vessel sit two electrodes 4 opposite each other. The seals 6 are designed as capillaries, in which an electrode system 16 is sealed by means of glass solder 19. From the capillary 6 in each case a supply line 5, which is connected to the associated electrode 4 in a known manner, projects. This is connected via a power supply 7 and a pinch with foil 12 with a base contact 13. The contact 13 is seated at the end of an outer bulb 10 surrounding the discharge vessel.

In Figure 2, the end portion is shown in detail. The capillary 6 is here integrally attached to the discharge volume. The capillary has an inner diameter D1, which is selected so that the electrode system fits straight into it. To reduce the dead volume, a molybdenum dan-helix wrapped around a bushing. This Mo spiral is not absolutely necessary. At the end of the capillary facing the discharge, a constriction 20 is integrally attached with a given length L and a reduced, approximately constant diameter DE. The diameter DE is chosen so that the electrode head just fits through it.

Figure 3 shows an embodiment in which the constriction 21 is shaped so that the diameter is not constant, but gradually widens behind the diameter of the capillary. In general, the diameter at the bottleneck can also change V-shaped, so it does not necessarily have to be constant over a range. The bottleneck does not necessarily have to sit directly at the beginning of the capillary, it can also be set a little further back. Preferably, however, the narrowest point with the minimum diameter should be in the range of the first 10% of the total length of the capillary. Normally, the annular bottleneck has procedural reasons rounded corners.

Figure 4 shows an embodiment in which the constriction 22 is designed as a separate ceramic ring or metal ring which is clamped in the capillary.

As a glass solder is a known glass solder, see for example WO 2005/124823.

As filling for the discharge vessel, any known metal halide is suitable. However, the system is particularly suitable for filling systems that are a halide of the Cerium included. For example, a filling can be used as in WO9825294, US6525476 or WO9928946.

Claims

claims A high pressure discharge lamp comprising an elongated ceramic discharge vessel having at its ends an electrode system sealed in a seal, the seal comprising a capillary having a given inner diameter ID, the electrode system comprising an electrode head, a shaft, and a bushing , characterized in that the capillary has a constriction in the vicinity of the end facing the discharge volume, whose diameter is reduced relative to the diameter ID. 2. High-pressure discharge lamp according to claim 1, characterized in that the diameter in the region of the constriction is adapted to the diameter of the electrode head from the outside. 3. High-pressure discharge lamp according to claim 1, characterized in that the length of the constriction is 0.5 to 3 mm. 4. High-pressure discharge lamp according to claim 1, characterized in that the bottleneck their minimum Inner diameter achieved in a region corresponding to the first 10% of the length of the capillary. 5. High-pressure discharge lamp according to claim 1, characterized in that the discharge vessel contains a filling of at least one metal halide, which uses cerium at least as metal.