EP0276888A2 - Gas-discharge lamp - Google Patents

Abstract

In the case of a gas discharge lamp with a discharge vessel (1) made of translucent material and containing an ionizable gas filling, which is surrounded at a distance by a translucent outer envelope (7), the discharge vessel has a heat-insulating, translucent envelope (8) made of a microporous airgel.

Description

The invention relates to a gas discharge lamp with a discharge vessel containing an ionizable gas filling and made of translucent material, which is surrounded at a distance by a translucent outer envelope, the discharge vessel having a heat-insulating, porous, translucent envelope within the outer envelope.

Gas discharge lamps, especially high pressure gas discharge lamps, have a discharge vessel made of translucent and heat-resistant material, e.g. made of quartz glass or sintered aluminum oxide. Common gas fillings of such lamps contain e.g. Sodium and / or mercury, optionally with additions of metal halides to improve color rendering. For thermal insulation of the discharge vessel, it is known to surround it with a single or double-walled quartz glass tube (US Pat. Nos. 29 72 693 and 32 50 934). To further reduce heat dissipation, the space between the discharge vessel and the outer bulb has been evacuated. In many cases, especially with low power gas discharge lamps, e.g. less than 70 W, the thermal insulation of the discharge tube by external quartz glass tubes is not sufficient, since the distance between the discharge tube and the outer shell is too small.

From GB-PS 481 320 a gas discharge lamp of the type mentioned is known, the covering being made of glass wool. Such an envelope causes a strong scattering of the light emanating from the discharge vessel, which makes it difficult to focus it. Around To avoid this, such a covering may only have a relatively loose packing, but this limits the thermal insulation.

The invention has for its object to provide a gas discharge lamp with a sheath, which brings about good thermal insulation of the discharge vessel, but at the same time either not at all or only slightly influences the emitted light.

This object is achieved in a gas discharge lamp of the type mentioned at the outset according to the invention in that the envelope is a microporous airgel which at least partially encloses the discharge vessel.

Such a microporous airgel consists of a cross-linked and open-pored solid structure of low density (less than 10% of the density of a solid body made of the material). All cavities between the solid particles have transverse diameters that are smaller than the light wavelength and e.g. between 0.03 and 0.2 µm, preferably between 0.04 and 0.07 µm. An airgel of this type therefore causes only a very slight scattering of the light.

The envelope of the discharge vessel can e.g. consist of silicon dioxide airgel or aluminum oxide airgel. Such aerogels are particularly heat-resistant. Their light absorption is negligible.

The thermal insulation brought about by these aerogels reduces the thermal radiation of the discharge vessel in such a way that the connected load of the lamp can be reduced, or for a given one, if the vessel dimensions are still technically manageable Performance can be used on larger vessel dimensions, which enables easier production.

According to a further development of the gas discharge lamp according to the invention, the envelope is a coherent mass which tightly surrounds the discharge vessel. In this development, the discharge vessel can be encapsulated with the airgel. In addition to thermal insulation, such a covering offers excellent protection against explosion of the discharge vessel. When the discharge vessel is completely covered with the airgel, the temperature distribution on the discharge vessel becomes more uniform. This has a beneficial influence on a number of lamp properties, e.g. stable color rendering, positional independence of the lamp and mechanical strength by lowering peak temperatures and thus reducing the tendency to recrystallization of the discharge vessel.

The space between the discharge vessel and the outer envelope can be completely filled with airgel. This has the advantage that the airgel can at the same time serve as a mechanical holder for the discharge vessel and thus further holders that obstruct light emission can be omitted. The envelope can consist of airgel particles or of a coherent mass. Such a mass is advantageous because light scatter at the boundary from the airgel and the outer shell is reduced.

If, according to a further embodiment of the gas discharge lamp according to the invention, the discharge vessel is at least partially covered with a molded body made of airgel that is adapted to its outer shape, this molded body can be produced separately and placed on the discharge vessel during lamp assembly.

If electrodes are accommodated in the discharge vessel, the sheathing can be in two parts and envelop the discharge vessel only in the area of the lamp electrodes. It has been found that such a covering surrounding only the lamp electrodes can be sufficient as thermal insulation.

The sheathing of the discharge vessel with an airgel reduces the requirements for a vacuum between the discharge vessel and the outer sheath and for the heat resistance of the outer sheath, so that, according to a development according to the invention, the latter can be made of plastic.

According to a further embodiment according to the invention, the outer shell is designed as a reflector, i.e. the outer shell is provided with a reflective layer on its outside or inside. In this case, the gas discharge lamp can be used as a lamp.

The lamp according to the invention can be a high-pressure gas discharge lamp, but also a low-pressure sodium vapor discharge lamp.

• Fig. 1 einen teilweisen Längsschnitt durch eine Hochdruck-Metallhalogenidentladungslampe, deren Entladungsgefäß mit einem Aerogel umgossen ist,
• Fig. 2 einen teilweisen Längsschnitt einer Niederdruck-­Natriumdampfentladungslampe, bei welcher der Raum zwischen Entladungsgefäß und Außenhülle mit Aerogelteilchen gefüllt ist,
• Fig. 3 einen Längsschnitt durch eine Hochdruck-Natrium­dampfentladungslampe, deren Enden eine Umhüllung aus Aerogel haben,
• Fig. 4 einen teilweisen Längsschnitt durch eine Hochdruck-Metallhalogenidentladungslampe, deren Außenhülle als Reflektor ausgebildet ist.

Some embodiments of the lamp according to the invention will now be explained in more detail with reference to the drawings. Show it:

• 1 is a partial longitudinal section through a high-pressure metal halide discharge lamp, the discharge vessel is cast with an airgel,
• 2 shows a partial longitudinal section of a low-pressure sodium vapor discharge lamp, in which the space between the discharge vessel and the outer envelope is filled with airgel particles,
• 3 shows a longitudinal section through a high-pressure sodium vapor discharge lamp, the ends of which have an envelope made of airgel,
• Fig. 4 is a partial longitudinal section through a high-pressure metal halide discharge lamp, the outer shell of which is designed as a reflector.

The high-pressure metal halide discharge lamp according to FIG. 1 has a discharge vessel 1 made of quartz glass, in which an ionizable gas filling and two electrodes 2 are accommodated, the connecting wires 3 of which are welded to intermediate pieces 4, which in turn are connected to strong pole wires 5, which are connected to a lamp base 6 are connected. The discharge vessel 1 is surrounded at a distance by a glass outer shell 7.

The discharge vessel 1 is inside the outer envelope 7 with a porous, translucent envelope 8 made of an airgel, e.g. Silicon dioxide airgel. In this case, the discharge vessel 1 is completely encapsulated with the airgel 8. (The production of silicon dioxide airgel is described in "Journal of Non-Crystalline Solids" 82 (1986), pages 265 to 270, Amsterdam.)

The low-pressure sodium vapor discharge lamp shown in FIG. 2 has a U-shaped discharge vessel 9, which has an ionizable gas filling and is provided with lateral bulges 10 for receiving sodium. At the ends of the U-shaped discharge vessel 9 there are electrodes 11, the connections of which are connected to a lamp base 12. The discharge vessel 9 is surrounded by a glass outer shell 13 at a distance. The space between the discharge vessel 9 and the outer envelope 13 is covered with microporous, spherical airgel particles 14 filled, which form a translucent envelope of the discharge vessel 9.

The high-pressure sodium vapor discharge lamp according to FIG. 3 has a tubular discharge vessel 15 made of translucent aluminum oxide. The ends of the discharge vessel 15 are closed with ceramic plugs 16, in which current supply wires 17 to electrodes 18 are received. Shaped bodies 19 made of airgel, in particular aluminum oxide airgel, are placed on the ends of the discharge vessel 15 and envelop the discharge vessel 15 only in the area of the lamp electrodes 18.

The high-pressure metal halide discharge lamp according to FIG. 4, designed as a radiator, has a discharge vessel 20 which is accommodated in an outer envelope 21 made of glass or plastic. The lamp structure essentially corresponds to the lamp according to FIG. 1. However, the outer envelope 21 has a parabolic shape and is covered on the inside with a reflection layer 22. The space between the discharge vessel 20 and the outer envelope 21 is completely filled with airgel 23.

In the case of a high-pressure metal halide vapor discharge lamp according to FIG. 1 with a connected load of 35 W without a cover, the connected load was reduced to 20 W by the airgel covering of the discharge vessel at the same color temperature. Surprisingly, there was also an improvement in the luminous efficacy from 78 to 86 lm / W. The density of the silica airgel was 0.16 g / cm³, while the density of quartz glass is 2.2 g / cm³.

The operating conditions of the lamps described are largely independent of the gas pressure in the outer envelope. The otherwise usual geometrical position dependence of the color temperature is significantly reduced; for example, 1, the difference in color temperature between the vertical and horizontal position of the discharge from 700 to 200 K. The aerogels made of silicon dioxide or aluminum oxide are UV-resistant. The described airgel envelopes of the discharge vessels show no noticeable absorption of the emitted radiation in the visible spectral range. These airgel casings are heat-resistant up to approximately 1000 ° C.

Claims (10)

1. gas discharge lamp with a discharge vessel containing an ionizable gas filling and made of translucent material, which is surrounded at a distance by a translucent outer envelope, the discharge vessel having a heat-insulating, porous, translucent envelope within the outer envelope,
characterized in that the envelope is a microporous airgel which at least partially encloses the discharge vessel. 2. Lamp according to claim 1,
characterized in that the envelope is a silicon dioxide airgel. 3. Lamp according to claim 1,
characterized in that the envelope is an alumina airgel. 4. Lamp according to one of claims 1 to 3,
characterized in that the envelope is a coherent mass. 5. Lamp according to claim 4,
characterized in that the mass fills the outer shell. 6. Lamp according to one of claims 1 to 3,
characterized in that the outer shell is filled with airgel particles. 7. Lamp according to one of claims 1 to 3,
characterized in that the covering consists of shaped bodies which are adapted to the shape of the discharge vessel. 8. The lamp as claimed in claim 7, in the discharge vessel of which electrodes are accommodated,
characterized in that the discharge vessel is enveloped by shaped bodies only in the region of the lamp electrodes. 9. Lamp according to one of the preceding claims,
characterized in that the outer shell is made of plastic. 10. Lamp according to claim 5,
characterized in that the outer shell is designed as a reflector.

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