DE2718527A1 - High pressure discharge lamp with ferrous spectral output - has ferrous halide and mercury containing filling and closely spaced electrodes - Google Patents

Abstract

The discharge tube of the lamp is made of quartz glass, and is mounted in UV radiation transparent outer bulb. The discharge tube filling contains a rare gas and ferrous halide as ignition gas providing ferrous spectral line output. The lamp filling contains a certain amount of mercury taking part in the discharge. The discharge tube has small dimensions and the distance of electrodes is less than 22 mm. The distance ratio to the tube inner diameter is less than 3.0 and more than 1, 2, the electrodes being hollow. The mercury is added in an amount of 1.0 to 2.5 mg per cu. cm. The metallic iron does not exceed 3 mg per cu. cm, and iodine is preferably used for the halide compound.

Description

The Irfindung concerns a spectral lamp with those in the generic term

de main claim mentioned features, the iron (II) halide to Exciting the iron line spectrum contains.

According to DT-OS 23 63 843 an iron spectral lamp is known at the rare gas iron iodide (FeJ2) and hydrogen, which make ignition easier is entered into the discharge vessel. About a diffusion of the hydrogen Avoid getting out of the discharge vessel during operation is also in the outer bulb of the lamp, hydrogen is present, the hydrogen partial pressures in the discharge vessel and should be the same in the outer bulb at operating temperature. To prevent electrical breakdowns in the outer bulb, this still has an extinguishing gas, preferably Nitrogen. The discharge vessel is due to the hydrogen content in the filling not to be arbitrarily minimal; Dimensions of a certain size must be adhered to to make it difficult for the hydrogen to diffuse out. The relatively large ones The dimensions of the discharge vessel and the outer bulb naturally make this use unwieldy compared to lamps of the usual spectral lamp series (mercury, Sodium, cadmum spectral lamps etc.), which are matched to one another in terms of their dimensions are. Compared to the otherwise known devices that excite the iron line spectrum are used, this iron spectral lamp already represents some progress It forms a closed system, similar to the hollow cathode flanges, but has a greater line intensity compared to those. However, this does not come approach that of the open iron arch.

In the case of the hollow cathode lamps, the iron spectrum is determined with the aid of a Glow discharge generated, which attaches to a hollow cathode made of iron material. The spectral lines are extremely sharp, but only of low intensity, so that long exposure times are necessary to record the spectrum. In addition to the desired With such a low-pressure discharge, the so-called spark spectrum also occurs that makes a quick orientation in the line spectrum very difficult. At the open Iron bows do not have this disadvantage, a pure arc spectrum is given off. This is also very strong in intensity, which enables shorter exposure times.

The disadvantage of the open iron arch is that it is cumbersome to use and, since work is done in open space, also the relatively unclean way of working.

There is also a UV lamp (DT-PS 18 Ol 834) that is used for therapeutic and cosmetic purposes or intended for use in the graphic industry is known, which is based on a mercury vapor high pressure discharge and the In addition to a noble gas as ignition gas, an additive for filling iron and / or Contains manganese halide; for example, 0.01 to 1 mg / cm³ of metallic iron should be used and an amount of halogen (iodine) equivalent to the iron (II) halide may be contained. Since this spotlight is designed for a completely different purpose, it is apart from the dosage of the iron (II) halide, a version that makes use as a compact spectral lamp unsuitable. Even with the one in the exemplary embodiment The above-mentioned 400 watt radiator would not result in a reduction in size of the discharge vessel stable operable spectral lamp. It would reignition after each Zero crossings of the AC voltage supply make difficulties and the service life these lamps would be insufficient.

The invention is based on the object of producing a spectral lamp of the iron line spectrum - only spectrum of the iron arc - to create the compact one Has dimensions and for normal operation (with standard series reactor) suitable is. The lamp should be easy to use and quickly ready for use as well as interchangeable with other spectral lamps of the usual spectral lamp series be. Compared to the well-known iron spectral lamps, the intensity is higher Spectral lines desired.

The spectral lamp with a discharge vessel made of quartz glass that is connected to has fused electrodes at the ends and one that is permeable to UV radiation Outer bulb is surrounded and iron (II) halide as a filling in addition to a noble gas as ignition gas for exciting the iron line spectrum, is characterized according to the invention, that the filling also contains a proportion of mercury which contributes to the discharge and the dimensions of the discharge vessel are kept small, that is to say that the electrode spacing is less than 22 mm, the ratio to the inner diameter of the discharge vessel is less than 3.0 and greater than 1.2, and that the electrodes are designed as hollow electrodes.

The mercury, which is in an amount of 1.0 to 2.5 mg / cm³ in the discharge vessel is contained and contributes to the discharge, results in the characteristic mercury lines in the spectrum, which are known to be very intense. These mercury lines allow a quick orientation in the very linear spectrum of iron (over area from 200 to 700 nm). Since a high pressure discharge takes place, only the so-called comes Arc spectrum; the disruptive iron spark spectrum does not occur. The education of the iron (II) halide amount of metallic iron contained in the discharge vessel can be 0.03 to 3 mg / cm³. A lot of has proven to be particularly beneficial 0.08 to 0.13 mg / cm³ has been shown.

The halogen is equivalent to the formation of the ferrous halide Quantity available; iodine is preferably used. The equivalent dosage is a high degree of constancy of the intensity ratios of the lines during the service life achieved. The size of the discharge vessel should be chosen so that the lamp with surrounding envelope is adapted to the usual spectral lamp series.

This also meets another requirement, namely that a A certain high wall load should be present at which a complete evaporation of the iron (II) halide takes place; at a high iron halide vapor pressure intense iron radiation. The wall load should be 6 to 12 Vatt / cm² lie. A discharge vessel size has proven to be useful in which the electrode spacing is about 17 mm and a ratio to the inner diameter of the discharge vessel from 1.5 to 1.7 is given. Such a discharge vessel cannot be used with the electrodes wound in the usual way (with these, the electrode rod protrudes the helix pushed out, forming a so-called electrode tip) operate stably; the lifetimes achieved are also inadequate. As beneficial so-called hollow electrodes have been found, dis preferably by - only formed with a part of their turns - vendula pushed onto a core pin are.

The Vendeln have proven to be favorable up to about half of their size Apply length to the core pins. Through the hollow-shaped electrodes is a A certain heat build-up achieved by the opposite to an operation with usual Electrodes result in improved ignition and operating properties. The ignition tips after the respective zero crossings of the AC power supply are much smaller, and a stable, burning arc can develop. Of the Arch attachment lies in the cavity of the helix, which results in an atomization as far as possible is prevented. As a material for both the core pins and the postponed ones Pure tungsten is advantageously used for coils. Around the 1 taking place in the lamp Not to influence the circular process and to avoid disturbing lines Electrode material does not have any additives that promote emissions or there are none such additives applied to the electrodes. Because of the small dimensions of the vessel the shape of the electrode spaces is also critical. You have to be ready right now that no inadmissibly high re-ignition peaks occur during the start-up phase, but so narrow that the wall temperature for the evaporation of the iron (II) halide is high enough. Paraboloid-shaped electrode spaces have proven useful. The ends of the discharge vessel can then be without heat-reflecting coatings. The that The outer bulb surrounding the discharge vessel is without protective gas; he's just evacuated. In contrast to the well-known iron spectral lamp, the burner could use iron iodide and hydrogen, can also be operated without an outer bulb. An outer bulb offers however, easier handling; the dimensions are of the usual spectral lamp series adapted and at the lower end a so-called Pico9 socket is attached (this has multiple pins).

The spectral lamp is operated on 220 volt mains voltage and A normal choke is used as the ballast. Used to ignite the lamp a conventional igniter generating voltage peaks of 3 to 4.5 kilovolts or a so-called starter.

The invention is reproduced with reference to one in the following figures Exemplary embodiment illustrated: Figure 1 shows a spectral lamp in side view.

Figure 2 is a partial view of one of the electrodes of the lamp reproduced in section.

The spectral lamp 1 shown in Figure 1 - approximately natural Size shown - consists of a discharge vessel (burner) 2 made of quartz glass, which is surrounded by an outer bulb 3, preferably made of UV-permeable hard glass is. The electrodes 6 and 7 are melted into the burner 2 at the pinch ends 4, 5. The waterproofing takes place via molybdenum foils 8, 9. The burner 2 is supported by the frame structure 10. The side rod 11 serves as a Power supply for the upper electrode 7 via the conductor connection 12. The power supply the lower electrode 6 takes place via a stranded wire 13. In the case of the outer bulb 3, the advantageous is pumped, the piston tip 14 is provided on the inside with a getter mirror.

At the lower end, the outer bulb 3 has a so-called Pico9 base 15. This is provided with the connector pins 16, with over two of the connector pins 16 the power is supplied. The electrode spacing d in the discharge vessel 2 is 17 mm and it is a ratio to the inner diameter of the discharge vessel 1 of this is 10.5 mm, given by 1.6. The electrodes 6, 7 are designed as hollow electrodes (explained in more detail in FIG. 2) and the shape of the electrode spaces is paraboloid. The burner 2, which has a volume of 2.1 cm3, contains mercury (Hg) in an amount of 2.2 mg. Iodide (J) is obtained by entering mercury iodide (HgJ2) contain; the dosage is 1.6 mg. In addition, metallic iron (Fe), for example as iron chips, added in an amount of 0.2 mg. As ignition gas is Argon is used, which has a pressure of 30 torr. When the discharge vessel is burned in Iron (II) iodide (FeJ2) is formed, which dissociates when the lamp is in operation; it comes for emitting the iron spectral lines. At the same time, the relatively strong ones also kick Mercury spectral lines that allow rapid orientation in the multi-line spectrum of iron. The spectral lamp has a power consumption of around 70 Watt and can, for example, be connected to a 125 watt high pressure mercury lamp Matched choke can be operated on the 220 volt network. A with can be used for ignition a glow igniter aI: s-approved starter can be used.

In Figure 2 is one of the two hollow electrodes 6, 7, the ii burner vessel the spectral lamp are melted down, shown enlarged. On a core pin 17 made of tungsten, a helix 18 made of tungsten and having a plurality of turns is pushed on. Since the helix 18 is only applied to the core pin 17 up to about half its length is, a cavity 19 is formed in which the discharge arc can attach. at This arrangement prevents the electrode coil from falling off 18th dusting material reaches the walls of the burner.

A stable, burning arc can develop. That for the electrodes 6, 7 Uses Tungsten does not contain any additives that promote emissions; there are also no such additional seats applied to the parts 17, 18.

The iron spectral lamp according to the invention can be used as a direct replacement for the open iron arch can be used. The iron arc spectrum emitted is intense and a stable burning discharge arc creates reproducible intensity conditions; the lamp is an excellent calibration standard. Due to the simultaneously occurring Mercury lines are a quick guide. The spectral lamp is handy due to its compact dimensions and allows quick use, not least because of their simple operation. This iron spectral lamp can be exchanged for a large number of other, coordinated spectral lamps.

Claims (11)

Spectral lamp for generating the iron line spectrum 0) claims / r 1. Spectral lamp with a. Discharge vessel made of quartz glass, the one fused at the ends Has electrodes and surrounded by an outer bulb permeable to UV radiation and that as a filling in addition to a noble gas as ignition gas iron (II) halide 2um Exciting the iron line spectrum, characterized in that in the filling it also contains a proportion of mercury that contributes to the discharge and the Dimensions of the discharge vessel are kept small, that is, the electrode spacing is less than 22 mm, the ratio to the inner diameter of the discharge vessel is less than 3.0 and greater than 1.2, and that the electrodes are hollow electrodes are formed. 2. Spectral lamp according to claim 1, characterized in that the Mercury is contained in the discharge vessel in an amount of 1.0 to 2.5 ig / cm3. 3. Spectral lamp according to claim 1 and 2, characterized in that the amount contained in the discharge vessel for the formation of the iron (II) halide of metallic iron is 0.03 to 3 mg / cm³. H Ol J 7/02 4. Spectral lamp according to claim 3, characterized characterized in that the amount of metallic iron is 0.08 to 0.13 mg / cm3. 5. Spectral lamp according to claim 1 to 4, characterized in that an amount of iodine equivalent to the formation of the iron (II) halide is used as the halogen is. 6. Spectral lamp according to claim 1 to 5, characterized in that the electrode spacing is about 17 mm and a ratio to the inner diameter of the discharge vessel is given from 1.5 to 1.7. 7. Spectral lamp according to claim 1 to 6, characterized in that the hollow electrodes through only part of their turns on a core pin deferred spirals are formed. 8. Spectral lamp according to claim 7, characterized in that the Coils are pushed onto the core pin up to about half their length. 9. Spectral lamp according to claim 7 and 8, characterized in that the coils and core pins that form the hollow electrodes are made of pure tungsten. 10. Spectral lamp according to claim 7 to 9, characterized in that the material used for the electrodes does not contain any additives that promote emissions contains or no such additives are applied to the electrodes. 11. Spectral lamp according to claim 1 to 10, characterized in that that the outer bulb surrounding the discharge vessel is tubular and at its lower one End carries a socket provided with several connector pins.