EP0547374A1 - Gastight sealed gas discharge lamp - Google Patents

Abstract

The invention relates to a gas-tight gas discharge lamp which is filled with a nitrogen-oxygen mixture at reduced pressure and in which a discharge current flows during operation. Such gas discharge lamps are used in particular in devices for determining the concentration of gases which absorb in the ultraviolet spectrum from 200 to 300 nm, such as. B. nitric oxide used. During operation of the gas discharge lamp, the oxygen contained in the nitrogen-oxygen mixture is consumed, which is required for the emission of nitrogen oxide radiation. In order to extend the life of the nitrogen oxide radiation of the gas discharge lamp, the nitrogen-oxygen mixture in the gas discharge lamp is enriched with water vapor. In addition, a water vapor-storing medium, such as manganese dioxide, is arranged in the gas discharge lamp and emits water vapor when the gas pressure in the gas discharge lamp drops. When the gas discharge lamp is operated, the oxygen required for the emission of nitrogen oxide radiation is obtained from the water vapor within the discharge zone. A further extension of the life of the nitrogen oxide radiation of the gas discharge lamp is achieved by releasing the stored water vapor by heating the medium storing water vapor. Devices which contain such gas discharge lamps are particularly suitable as operating photometers for applications in the industrial sector. <IMAGE>

Description

The invention relates to a gas-tight gas discharge lamp which is filled with a nitrogen-oxygen mixture at reduced pressure and in which a discharge current flows during operation.

Such gas discharge lamps are used in particular in photometers to determine the concentration of gases contained in a gas mixture, which absorb in the ultraviolet spectrum from 200 to 600 nm, such as. B. nitrogen oxide or sulfur dioxide. Hollow cathode lamps usually serve as the gas discharge lamps.

A photometer for determining the concentration of nitrogen oxide is known from DE-PS 25 41 162. This photometer contains a gas discharge lamp in the form of a carbon cathode lamp filled with air at negative pressure, which is operated with a low discharge current, and a radiation detector for receiving the nitrogen oxide resonance radiation emitted by the hollow cathode lamp after passage through the gas mixture.The hollow cathode lamp is sealed in a vacuum-tight manner, the pressure in the hollow cathode lamp is 1 to 5 mbar. In the case of such a carbon cathode lamp, the life of the nitrogen oxide radiation is so short because of the oxygen from the nitrogen-oxygen mixture that is consumed during operation of the hollow cathode lamp that such a hollow cathode lamp can be used for laboratory applications without additional measures, but not is suitable for industrial applications. An increase in the pressure in the hollow cathode lamp increases the life of the nitrogen oxide radiation, but at the same time reduces the intensity of this radiation.

Another photometer with a gas discharge lamp in the form of a hollow cathode lamp is known from DE-PS 25 46 565. This photometer is primarily designed for the determination of sulfur dioxide in a gas mixture. According to one embodiment of the photometer, it is also provided for the additional determination of nitrogen oxide in a gas mixture. The hollow cathode lamp is filled with a dried nitrogen-oxygen mixture and is sealed in a vacuum-tight manner after it has been filled. Also for this photometer, the lifespan of the nitrogen oxide radiation of the hollow cathode lamp required for determining the concentration of nitrogen oxide is so short because of the oxygen consumed from the nitrogen-oxygen mixture during operation of the hollow cathode lamp that such a hollow cathode lamp can be used for laboratory applications without additional measures , but is not suitable for industrial applications.

After it had been recognized that the short lifespan of the nitrogen oxide radiation of a hollow cathode lamp, as is known from the abovementioned publications, for applications in the industrial sector for determining the concentration of gases which absorb in the ultraviolet spectrum from 200 to 300 nm, on the consumption of the Oxygen is due to the nitrogen-oxygen mixture, attempts have been made to replace the consumed oxygen with oxygen released by an oxygen-storing or oxygen-donating medium. It was assumed, among other things, that metal dioxides, such as manganese dioxide, decompose under reduced pressure or with an increase in temperature while releasing oxygen.

Such a hollow cathode lamp is known from DE-OS 29 25 410. The cabbage cathode lamp is filled with a nitrogen-oxygen mixture at negative pressure and sealed gas-tight. The influence of gas consumption is to be reduced by introducing a quantity of metal dioxide into the hollow cathode lamp. However, it has been shown that the oxygen release of the metal dioxide at the temperatures prevailing during operation of the hollow cathode lamp is too low to replace the consumed oxygen. The oxygen emitted by the metal dioxide due to the negative pressure prevailing in the carbon cathode lamp is also too low to replace the consumed oxygen.

The invention has for its object to improve a gas discharge lamp of the type mentioned so that the life of the used for the determination of the concentration of gases that absorb in the ultraviolet spectrum of 200 to 300 nm, extended.

This object is achieved in a generic gas discharge lamp by the features specified in the characterizing part of claim 1. The additional oxygen used to extend the life of the nitrogen oxide radiation is stored in the form of water vapor in the gas discharge lamp. The additional oxygen is only obtained from the water vapor added to the nitrogen-oxygen mixture during operation of the gas discharge lamp within the discharge zone. The invention is based on the finding that water vapor is stored in the gas discharge lamp instead of oxygen and that the oxygen required is only obtained from the water vapor when required. The storage of water vapor has the advantage over the direct storage of oxygen that even with the low pressure in the gas discharge lamp, which is of the order of 10 mbar, so much water vapor can be stored that the photometer can be operated for one year to determine the concentration of nitrogen oxide without having to replace the gas discharge lamp.

Advantageous developments of the gas discharge lamp according to claim 1 are characterized in claims 2 to 7. The pressure in the gas discharge lamp, which is increased to 5 to 20 mbar compared to the prior art (1 to 5 mbar), leads to a further extension of the life of the nitrogen oxide radiation with only a slightly reduced intensity of the emitted radiation. The water vapor-storing medium is advantageously contained in a storage vessel connected to the gas discharge lamp. By heating the water vapor storage medium contained in the storage vessel, water vapor is supplied to the interior of the gas discharge lamp if necessary. The use of manganese dioxide as a medium storing water vapor has proven to be particularly suitable, since it is chemically passive, stable under pressure and temperature and has a large storage capacity for water vapor. The stored water vapor can be released in a defined manner by metered heating. The gas discharge lamp is advantageously an electrodeless gas discharge lamp with high-frequency excitation or a hollow cathode lamp.

Figur 1

eine mit Hochfrequenz angeregte Gasentladungslampe gemäß der Erfindung und

Figur 2

eine als Hohlkathodenlampe ausgestaltete Gasentladungslampe gemäß der Erfindung.

Gleiche Teile sind mit denselben Bezugszeichen versehen.The invention is described below with reference to two exemplary embodiments. Show it

Figure 1

a high-frequency excited gas discharge lamp according to the invention and

Figure 2

a gas discharge lamp designed as a hollow cathode lamp according to the invention.

The same parts are provided with the same reference numerals.

FIG. 1 shows a gas discharge lamp excited with high frequency, which is made of glass. The lamp bulb 1 is from a coil 2 made of copper surround. An alternating current flowing in the coil 2 serves to excite the plasma formation in the gas discharge lamp. The frequency of the alternating current is of the order of 100 MHz. The lamp bulb 1 is connected to a reservoir 4 via a connecting tube 3. A small piston 5 is connected to the connecting pipe 3 and contains manganese dioxide 6 serving as a water vapor store. The manganese dioxide filling can be fixed in the flask 5 using glass wool. Arranged around the piston 5 is an electrical heating winding 7, only shown schematically, which is used to heat the manganese dioxide 6 if necessary.

The gas discharge lamp is filled with a nitrogen-oxygen mixture that is enriched with water vapor. The nitrogen-oxygen mixture is enriched with water vapor in a known manner. This can e.g. B. when passing the nitrogen-oxygen mixture through a vessel filled with distilled water, in which the desired water vapor partial pressure is set via the temperature of the water. The filling mixture produced in this way, which consists of the nitrogen-oxygen mixture with water vapor components, is passed through the gas discharge lamp. If the manganese dioxide has not already been moistened beforehand, the manganese dioxide serving as the water vapor-storing medium is also moistened. After setting the negative pressure of preferably 5 to 20 mbar required for the operation of the hollow cathode lamp, the gas discharge lamp is sealed gas-tight by melting.

If the pressure in the gas discharge lamp drops during operation of the gas discharge lamp due to gas consumption, water vapor is emitted by the manganese dioxide. In addition, water vapor can also be released by heating the manganese dioxide. The type and duration of the heating is chosen so that essentially only the oxygen consumed is supplemented, so that the oxygen partial pressure in the gas discharge lamp remains approximately constant in the long term. This results in a significant extension of the life of the nitrogen oxide radiation emitted by the gas discharge lamp, which is used to determine the concentration of gases in the ultraviolet spectrum from 200 to 300 nm. A photometer equipped with such a gas discharge lamp can be operated for one year to determine the concentration of nitrogen oxide without the gas discharge lamp having to be replaced.

FIG. 2 shows a gas discharge lamp designed as a hollow cathode lamp, which is made of glass. A cathode 8 and an anode 9 are located in the lamp bulb 1. The further construction of the hollow cathode lamp corresponds to that of the gas discharge lamp shown in FIG. In this exemplary embodiment too, water vapor is emitted from the manganese dioxide when the pressure in the hollow cathode lamp drops, the used oxygen being obtained from the water vapor within the discharge zone.

Claims (7)

Gas-tight sealed gas discharge lamp, which is filled with a nitrogen-oxygen mixture at negative pressure and in which a discharge current flows during operation, characterized in that that the nitrogen-oxygen mixture in the gas discharge lamp is enriched with water vapor, - That a dampened with water vapor-storing medium is arranged in the gas discharge lamp and - That the medium storing water vapor releases water vapor when the gas pressure drops. Gas discharge lamp according to claim 1, characterized in that the pressure in the gas discharge lamp is 5 to 20 mbar. Gas discharge lamp according to Claim 1 or Claim 2, characterized in that the medium storing water vapor is contained in a storage vessel connected to the gas discharge lamp. Gas discharge lamp according to Claim 3, characterized in that the water vapor-storing medium contained in the storage vessel is heated. Gas discharge lamp according to one of the preceding claims, characterized in that manganese dioxide is used as the water vapor-storing medium. Gas discharge lamp according to one of the preceding claims, characterized in that the gas discharge lamp is an electrodeless gas discharge lamp with high-frequency excitation. Gas discharge lamp according to one of claims 1 to 5, characterized in that the gas discharge lamp is a hollow cathode lamp.

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