EP2131383A2 - High pressure discharge lamp - Google Patents

Abstract

The lamp (1) has a discharge container enclosing a discharge volume, and electrodes extending into the discharge volume enclosed by the container. A filling containing metal halides is accommodated in the discharge volume. The discharge container is enclosed by an outer piston that is supported by a frame (21), where the outer piston is evacuated. The frame in the outer piston serves for the adjustment and maintenance of vacuum. The frame is partially or sectionally made of niobium and zirconium, where the frame is exposed in a temperature of 230 degree centigrades.

Description

Technical area

The invention relates to a high-pressure discharge lamp according to the preamble of claim 1. Such lamps are in particular high-pressure discharge lamps with a ceramic discharge vessel or quartz glass vessel for general lighting.

State of the art

The DE 199 51 445 discloses a high pressure discharge lamp in which an Nb getter is mounted on an electrode shaft in the discharge volume. The EP 790 639 discloses a high pressure discharge lamp using as getter Nb-Zr.

The EP 251 436 discloses a high pressure sodium lamp in which a Ba getter is mounted in the outer bulb and an Nb-containing getter is placed in the discharge vessel.

Presentation of the invention

The object of the present invention is to provide a high-pressure discharge lamp in which local heating of the discharge vessel is largely avoided.

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

Particularly advantageous embodiments can be found in the dependent claims.

A variety of discharge lamps use vacuum in the outer bulb. This vacuum serves on the one hand to operate the lamps thermally stable, because a filling gas in the outer bulb, for example, nitrogen, the lamp would be in operation cool. On the other hand, the vacuum protects lamp components that either oxidize, corrode or become brittle in contact with a filling gas, which leads to premature failure of the lamp.

The invention relates to a lamp frame, which has a getter effect. It turns out that a lamp frame made of niobium, niobium-zirconium, or Zr works from temperatures of at least 230 ° C as a getter in a lamp. The lamp frame or a component of the current feedthrough into the burner is brought sufficiently close to the burner to achieve the necessary temperature. In extreme cases, even a contact between the lamp frame and discharge vessel is possible. Due to the heat radiation of the burner, the frame or component is activated. As a result, an existing vacuum is maintained or improved.

If a lamp frame with getter effect is used u.U. in addition, a cost saving in the lamp construction, since it can be dispensed with additional components (such as zirkongetter) and additional manufacturing processes / facilities.

It is known per se to introduce getters in the outer bulb, which maintain or even improve the vacuum. Known lamps use a zirkongetter in the outer bulb, which is welded to the lamp frame or to the burner. The vacuum technique used to adjust the outer bulb vacuum typically achieves a vacuum in the range of 10 ^-2 mbar. The getter activation then sets the desired vacuum in the range of 10 ^-4 mbar.

The disclosure of the invention describes a possibility to produce the required outer bulb vacuum in the range of 10 ^-4 mbar without an additional Getterplättchen (Zirkongetter).

Lamps with a ceramic discharge vessel already use a lamp frame made of niobium or niobium zirconium. Up to now, a small plate with a zircong-timer has been welded and activated during production. It has now been proven that this additional lamp component can be dispensed with. If the niobium / niobium zirconium component or another niobium / niobium zirconium component, which is fastened to the power supply lines of the burner, is passed only sufficiently close to the burner and this component is exposed to a temperature ≥230 ° C., this component unfolds a gettering effect , In contrast to the Zirkongetter, which immediately after activation improves the outer bulb vacuum of 10 ^-2 mbar to 10 ^-4 mbar, the getterable lamp frame requires a few burning hours until also sets a corresponding outer bulb vacuum. After 100 hours of burning, an identical outer bulb vacuum is measured, regardless of whether the lamp has a separate circulator or only a getterable lamp frame.

The discharge vessel is typically made of aluminum-containing ceramics such as PCA or YAG, AlN or AlYO3. but it can also consist of quartz glass. Both are known per se from the prior art. The choice of filling is subject to no particular restriction.

Brief description of the drawings

Fig. 1

eine Hochdruckentladungslampe mit Entladungsgefäß und Getter nach dem Stand der Technik;

Fig. 2

eine Hochdruckentladungslampe mit Entladungsgefäß, aber ohne Getter.

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

Fig. 1

a high-pressure discharge lamp with discharge vessel and getter according to the prior art;

Fig. 2

a high-pressure discharge lamp with discharge vessel, but without getter.

Preferred embodiment of the invention

FIG. 1 schematically shows a metal halide lamp 1. It consists of a discharge vessel 2 made of ceramic, in which two electrodes 3 are inserted. The discharge vessel has a central part 5 and two ends 4. At the ends sit two seals 6, which are designed here as capillaries. Preferably, the discharge vessel and the seals are integrally made of a material such as PCA.

The discharge vessel 2 is surrounded by an evacuated outer bulb 7. The discharge vessel 2 is in the outer bulb by means of a frame 11, which includes a short and long power supply 11 a and 11 b, supported.

The frame is made of Nb-wire or Mo-wire or similar. manufactured. In the specific case of a 70 W lamp with metal halide filling, the diameter of the frame wire is typically 0.5 to 1.5 mm. A Getter plate 12 with Zr is attached to the frame.

FIG. 2 schematically shows a similar metal halide 1. It is identical in construction as the first lamp. However, it is important here that the frame 21, ie both the short wire 21a and the long wire 21b, made of niobium, Zircon, or a Nb-Zr alloy is made. But it is possible that only the long frame wire 21b is made of this material.

Furthermore, it is important that the distance between the discharge vessel and the long frame wire 21b is dimensioned so narrow, advantageously in the area of the bulge 5, that the frame wire 21b reaches a temperature of at least 230 ° C. during operation. The diameter of the frame wire is unchanged.

Preferred is the frame of niobium wire to which at least 0.1 mole% of Zr has been added.

In one-sided socketed lamps, in which the long bracket wire 21b is returned directly to the discharge vessel along, it is not necessary to make a change in the frame assembly to dispense with the additional getter in the evacuated outer bulb can. On the other hand, in the case of double-ended lamps, care must be taken to ensure that a frame wire is brought close enough to the discharge vessel. Of course, it is also sufficient if only a part of the frame, for example one of the two wires or a wire section, which is exposed to a sufficiently high temperature, from the getterwirksamen material, namely Nb or Zr or an alloy thereof is formed. The remaining part of the frame may be made of other material, in particular, this applies to the short frame wire in a single-ended lamp.

Depending on the volume of the outer bulb, more or less time is needed until the desired vacuum, without extra Getterplättchen adjusts. However, the time is always only in the range of a few hours.

The typical best effective distance of the frame part to the discharge vessel is in the range 0.2 to 2 mm.

The lamp may or may not contain electrodes. The filling may or may not contain metal halides. It can also be a high-pressure sodium lamp.

A comparison of the development of the vacuum in lamps according to the prior art and lamps according to the invention, in which the frame acts as a getter, shows Tab. 1 and 2. It can be seen that the frame as a getter only takes a little longer time, but finally a guarantee equal good vacuum. Tab. 1 0 hours 3x10 ^-4 mbar 1 H. 4x10 ^-4 mbar 25 hours 6x10 ^-4 mbar 100 hours 1,1x10 ^-3 mbar 0 hours 3x10 ^-2 mbar 1 H. 2x10 ^-4 mbar 25 hours 5x10 ^-4 mbar 100 hours 9x10 ^-4 mbar

Claims (5)

High-pressure discharge lamp with a discharge vessel surrounding a discharge volume, wherein in particular electrodes extend into the discharge volume enveloped by the discharge vessel, and wherein a filling containing in particular metal halides, is housed in the discharge volume, wherein the discharge vessel is surrounded by an outer bulb and it by a frame is held, characterized in that the outer bulb is evacuated, and a getter in the outer bulb for adjusting and maintaining the vacuum is used, wherein a frame which consists at least partially or partially of Nb, Zr or an alloy of these two metals, and shaped so in that at least in an area consisting of Nb, Zr, or its alloy is exposed to a temperature of at least 230 ° C, preferably at least 300 ° C, during operation, so that the frame itself is used as a getter. High-pressure discharge lamp according to claim 1, characterized in that the outer bulb is closed on one side, wherein the frame has a long stirrup wire, which is returned from the sockelfernen end of the outer bulb to the closure of the outer bulb. High-pressure discharge lamp according to claim 1, characterized in that the minimum distance between the frame and discharge vessel is at most 2 mm and preferably in the range 0.2 to 2 mm. High-pressure discharge lamp according to claim 1, characterized in that the lamp has a longitudinal axis, and the frame over at least an axial length of 5 mm is guided along the discharge vessel so that its operating temperature is at least 230 ° C. Use of a frame wire of Nb, Zr, or an alloy thereof in a high-pressure discharge lamp as getter, wherein the high-pressure discharge lamp is equipped with a discharge vessel surrounding a discharge volume, in particular electrodes extending into the discharge volume enveloped by the discharge vessel, and wherein a filling, which is in particular metal halides, is accommodated in the discharge volume, the discharge vessel being surrounded by an outer bulb and supported therein by a frame, the outer bulb being evacuated, the frame being shaped such that it is formed at least in a region consisting of Nb , Zr, or their alloy is exposed during operation to a temperature of at least 230 ° C.

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