NL7901479A - HIGH PRESSURE MERCURY DISCHARGE LAMP. - Google Patents

Description

* 26.2.1979 1 ΡΗΝ 9362 11.7, Philips * Light bulb factories in Eindhoven.

"High pressure mercury discharge lamp"

The invention relates to a high-pressure mercury discharge lamp with a vacuum-tight closed quartz glass lamp vessel with pinch seal, in which pinch seal a second metal-coated metal foil is received, on which an internal current conductor to an electrode arranged inside the lamp vessel and an external one current conductor, which lamp vessel is provided with a filling containing mercury, noble gas and metal halides.

Such a lamp is known from British Patent Specification 1,521,129. In the known lamp, the nip seal contains a molybdenum foil, which is coated with a layer of tungsten. The tungsten coating was applied because metal halides would penetrate the pinch seal 15, attack the molybdenum foil and nullify the adhesion of the quartz glass to the molybdenum foil. A two µm tungsten layer would prevent or delay deterioration of the film. The tungsten layer would preferably be up to ten or more / µm thick, provided that the total thickness of the film does not prevent the formation of a vacuum-tight nip.

It has been found that coating molybdenum films with tungsten is not a reliable means of prematurely failing high-pressure mercury lamps with metal 790 1 479

/ · V

26.2.1979 2 PHN 9362 to avoid halide additives,

The object of the invention is now to provide metal halides containing high-pressure mercury lamps, the gas density of the pinch seal being retained.

According to the invention, this object is achieved in the case of high-pressure mercury lamps of the type desired in the opening paragraph, that the metal foil is coated with a second metal, which is selected from the group consisting of Ta, Nb, V, Cr, Zr, Ti, Y, La, Sc and Hf.

When such a coated film is used, it is the reduction of the light output, due to the occurrence of blackening on the wall of the lamp vessel, that determines the, economical, life of the lamps.

The invention is based on an insight, which will be explained below. A few remarks follow by way of introduction.

The pinch seal of a lamp is, immediately after its manufacture, vacuum-tight over the part of the length of the metal foil located between the end of the internal current conductor and the end of the external current conductor. A capillary channel extends around both current conductors in the pinch seal. Via the channel around the internal current conductor, components from the filling of the lamp vessel, via the channel around the external current conductor, components from the atmosphere surrounding the lamp vessel can penetrate into the foil in the nip.

As metal foils, both molybdenum and tungsten foils can be used. These naturally have an oxide skin, which is important for good adhesion of quartz glass to the foil.

High-pressure metal halide mercury lamps contain one or more alkali metals, such as sodium and lithium, and one or more other metals such as indium, thallium, scandium, cadmium, zinc, lead and tin of group IIB, UIA, IIIB and IYA of the periodic table .

790 1 4 79 26.2.1979 3 ΡΗΝ 9362 ί%

According to the insight underlying the invention, the following reactions can now proceed in the pinch seal: 5 2SiO 2 + MoO 2 + 4NaHal ^ - »2Na? SiO 3 + MoHal ^ (l)

MoHal ^ + 4 In - »Mo + 4lnHal (2).

Here Na is a representative of the alkali metals, In a representative of the other metals and Hal represents 10 a halogen, for example iodine. The equilibrium (1) is strongly to the left, because the change of the free enthalpy is positive (Δ & ^> 0). The equilibrium (2), however, lies very strongly to the right, because AG2 <£ <0. Both reactions proceed in the lamp, because + AG2 0. The effect of these reactions is not, as stated in the British patent mentioned, erosion of the molybdenum foil, but a reduction of the oxide skin thereof, which leads to reduced adhesion of the foil to the quartz glass and leakage of the lamp vessel. In addition, the reactions result in the formation of sodium silicate, from which easily forms cryobalite, a crystalline form of quartz of less mechanical strength. The formation of cristobalite can result in the pinch seal jumping.

It has been found that these reactions also proceed, albeit that their effect is delayed when the concentration of a metal such as, for example, indium in the gas mixture is very low, such as when an excess of halogen is present. In that case, free indium can be formed in the lamp by discharge of ions at the electrodes.

By applying a separation between the metal foil and the quartz glass according to the invention, the course of the reaction (1) is made impossible. However, the second metal must have an oxide skin to achieve good adhesion to the quartz glass. In addition, the second metal should not initiate a similar reaction (1) 790 1 479 26.2.1979 4 PHN 9362. The second metals used according to the invention therefore have such a stable oxide that when using those metals Δ> O and ^ .G · ^ + Δ G · ,,> 0. Tungsten 5 does not meet this requirement. The metal foils coated with a second metal need not undergo special processing to form an oxide skin thereon. They automatically get it during the normal processes when manufacturing a lamp, as is the case with uncoated films of 10 molybdenum or tungsten.

Some of the metal halides used in high-pressure mercury discharge lamps are highly hygroscopic.

To avoid the introduction of water, the metal plus mercury halide is therefore dosed instead of the metal halide, from which the metal halide is then formed in the lamp vessel at an elevated temperature. However, it is practically impossible to meter metal and halogen in the stoichiometric ratio.

In view of the fact that, as a result of the measure according to the invention, a metal, such as indium, can no longer have an adverse effect on the adhesion of quartz glass to the metal foil, such metals can now be dosed in an excess with respect to halogen. The favorable effect of this is that, once the lamp has been at a high temperature, mercury halide is no longer present in the lamp. Namely, mercury halide is known to increase the ignition voltage and the re-ignition voltage of a lamp, even at very low partial pressures.

The use of excess metal may also serve to prevent mercury halide from forming during the life of the lamp due to reaction of the lamp vessel filling with impurities in its wall.

In a special embodiment, the part of the external current conductor located in the nip seal also consists, at least on the surface, of a metal selected from the group consisting of Ta, Nb, V, Cr,

Zr, Ti, Y, La, Sc and Hf. It is of course possible to also coat the external current conductor with this metal where it protrudes outside the lamp vessel 7901479 26.2.1979 5 PHN 9362, or - either the part located in the pinch seal or the entire external current conductor in solid form from one or more of the aforementioned me- 5 languages to exist. Generally, a coating of at least 0.01 µm thick will be chosen.

This embodiment has the advantage that alkali silicate formation around the external current conductor is prevented. Namely, it has been found that alkali metals (eg, sodium and lithium) are capable of migrating along the interface of the metal foil and quartz glass, without affecting adhesion, to the external current conductor. It is true that this migration and the formation of alkali metal silicate do not result in a tightness of the pinch seal, because a capillary space is already present around the external current conductor, but they do remove alkali metal from the discharge. As a result, the color of the discharge can change during the life of the lamp.

Surprisingly, it has been found that very thin layers on the metal foil have second metal / already have the desired effect.

In general, layers are used from 0.01 to 0.2 µm thick, in particular from 0.05 to 0.1 µm thick.

The coating can be obtained by vapor deposition, sputtering, electrolysis, ion plating, chemical vapor deposition, among others.

Since deterioration of the pinch seal of the lamp vessel occurs not only when using fused silica, but also when using glasses with a silicon dioxide content of at least 95% by weight and the invention also applies thereto, glass with a silicon dioxide content of at least 95 Sew. $.

An embodiment of a lamp according to the invention is shown in the drawing.

Fig. 1 is the side view of a lamp in an outer balloon, Fig. 2 is a detail of Fig. 1.

790 1 4 79 26.2.1979 6 PHN 9362

In Fig. 1, a discharge lamp 1 is arranged between current supply conductors 2 and 3 in an outer balloon 4, which is provided with a lamp base 5. Power supply conductor 3 is surrounded by a ceramic tube 6. The discharge lamp 1 has a quartz glass lamp vessel 10 closed with pinch seals 11 and 12, in which a metal foil 13 resp. 14 is included. An internal current conductor 15 and 14 are respectively attached to the metal foils 13 and 14. 16 to 10 an electrode 17 or 10 disposed within the lamp vessel. 18 and an external current conductor 19, respectively. 20 welded;

In Fig. 2, 30 denotes the zone between the ends of the internal 16 and the external current conductor, in which the pinch seal 12 is vacuum-tight over its entire width. A capillary cavity 31 and 31 respectively extends around the internal flow conductor 16 and around the external flow conductor 20. 32 out. The external current conductor 20 can already come into contact with oxygen and moisture from the air over its entire length immediately after making the pinch seal 12, while it is still at a high temperature, and thereby oxidize. The external current conductor 20 consists of molybdenum. The portion 33 located in the pinch seal 12 which may contact the glass is covered with tantalum. The foil 14 also consists of tantalum-covered molybdenum.

Example:

In a concrete case, a quartz glass lamp vessel was filled with 36 mg Hg, 5330 Pa Ar, 30 mg NaJ, 3 7 mg TIJ, 0.3 mg InJ and 2 mg In. The molybdenum foils and the molybdenum 30 external current conductors of the lamp were covered with 0.05 µm Ta. The lamp consumed a power of 400 ¥ during operation at 220 V. The pinch seals of the lamp remained vacuum-tight and no cryobalite formation was observed.

35 790 1 479

Claims (3)

26.2.1979 "f" pHN 9362 1. High-pressure mercury discharge lamp with a vacuum-sealed, quartz glass lamp vessel with pinch seal, in which pinch sealing a second metal-coated metal foil is received, to which an internal current conductor 5 is connected to an electrode arranged inside the lamp vessel and an external current conductor, which lamp vessel is provided with a filling containing mercury, noble gas and metal halides, characterized in that the metal foil is coated with a second metal selected from the group consisting of Ta, Nb, V, Cr, Zr, Ti, Y, La, Sc and Hf. High-pressure discharge lamp according to claim 1, characterized in that the part of the external current conductor located in the pinch seal consists at least on the surface of a metal selected from the group consisting of 15 Ta, Nb, Y, Cr, Zr, Ti, Y, La, Sc and Hf. High-pressure discharge lamp according to claim 1, characterized in that the second metal has a layer thickness between 0.2 and 0.01 yrum. 790 1 4 7 9 20