DE2752593A1 - DEVICE FOR GENERATING ULTRAVIOLET RADIATION - Google Patents

Abstract

In the case of a low-pressure gas-discharge lamp of high radiation intensity in the region of the 254 nm line, the structural design of the discharge tube (1), which is filled with mercury and noble gas and contains two discharge electrodes (3, 3'), is intended to be simplified and, at the same time, the life and efficiency are intended to be improved, while maintaining a high radiation intensity. This is achieved in that two thermoemissive electrodes (3, 3') are provided which are virtually identical in terms of their geometrical dimensions, their construction and their material composition and to which alternating current can be applied, and in that argon, krypton and/or xenon is provided as the noble gas, at a gas pressure of between 0.01 and 0.5 torr in the operating state of the discharge lamp. This lamp can be used as a high-current, low-pressure UV radiation source for killing germs in the food and packaging industries. <IMAGE>

Description

Device for generating ultraviolet radiation

The invention relates to a device for generating ultraviolet rays Radiation with high radiation intensity, in which the radiation in a UV radiation-permeable and a discharge tube provided with a mercury-noble gas filling between 4 and 20 mm lying inside diameter through a wall-stabilized, between two Electrodes gas discharge occurring at a pressure of mercury between 5.10-3 and 5.10 Torr, a pressure of the rare gas between 0.01 and 10 Torr and a current density of the discharge current of the gas discharge between 1 and 25 A / cm can be generated thermo-emissively is, and wherein the discharge tube at both ends with a tubular Piston is connected, in each of which one of the two electrodes is housed.

Such sources - called high-current, low-pressure UV radiation sources for short Equipment are for example from the DT-OS en 2412 997 and 21433 557 as well from Brandmüller-Moser, Introduction to Raman Spectroscopy, Steinkopff-Verlag, Darmstadt 1962, p. 146 ff known. To achieve a high radiation intensity such lamps are commonly used operated with direct current. For this two different electrodes are required, namely a thermoemissive cathode, such as a barium oxide cathode, and a high-energy electron receiving and therefore extremely heat-resistant anode, for example made of graphite. As when operating the radiation source with only a small pressure difference, a large mercury vapor flow from the anode compartment to the Cathode chamber has to flow, it is also necessary to have a pressure equalization chamber to be provided. However, electrophoretic processes in the discharge cannot be carried out Avoid, so that an uneven radiation over the entire surface of the discharge space occurs and premature aging of the radiation source occurs.

It is therefore the object of the present invention to provide a device of the aforementioned type, with which in the case of a simple structural design, especially at the wavelength 254 nm a high radiation intensity and a uniform radiation over the entire surface is achieved, and which is also characterized by a long service life and high level of efficiency.

This object is achieved in that two thermoemissive, with regard to the geometrical dimensions, the structure and the material composition to a large extent identical electrodes that can be charged with alternating current are present, and that as noble gases argon, krypton and / or xenon with one in the operating state of the device between 0.01 and 0.5 Torr lying gas pressure are provided.

In such a device there are no asymmetrical electrodes and no pressure equalization pipe necessary. Due to the appropriate setting of the noble gas pressure even with AC-powered radiation sources one comparable to the previously known direct current-operated radiation sources Radiation intensity achieved, in addition, because of the lack of electrophoretic Processes a uniform radiation over the entire surface of the discharge tube is achieved. It is also an advantage that the device is powered from the mains with a series reactor without the interposition of a rectifier.

Here it has proven particularly useful to use as electrodes oxide cathodes made of nickel powder and (Ba, Ca, Sr) carbonate, or one Tungsten, ilolybdenum or tantalum sintered bodies and barium or an earth metal containing dispenser cathodes are provided.

It is highly recommended that both contain the electrodes Pistons with regard to their geometrical dimensions and their material compositions are identical and made of the same material as the discharge tube, since the entire establishment is now symmetrical and is particularly simple and above all Can be produced without the use of horsetail.

For use in the food and packaging industry It is particularly favorable that the discharge tube and the two bulbs are made of doped Quartz glass, the doping being such that the lines at 185 and 194 nm are almost completely absorbed and the line at 254 nm is almost lossless is transmitted, since now the undesired caused by the absorbed lines Ozonization of the air is almost completely suppressed, whereas that caused by the The transmitted line caused the desired killing of germs to the full can be.

It is highly recommended that the xenon pressure be between 0.04 and 0.1 Torr, since xenon is precisely in this pressure range with regard to the discharge behavior properties similar to those of mercury at 55t and those according to the invention Device therefore started cold and / or without a standby circuit and extremely quickly can be driven up. Due to the fact that on the discharge tube an appendix-shaped, for receiving the mercury certain pipe section is provided, the temperature of which between 48 and fjo C is adjustable, the mercury vapor pressure and thus the entire device with regard to the emitted radiation intensity in particular regulate easily.

In a preferred embodiment of the device according to the invention it is recommended to choose the dimensions so that the inner diameter of the discharge tube between 8 and 15 mm, where, however, the diameter of the caecum-shaped pipe section 0.3 - l times and the diameter of the pistons 1 - 4 times the diameter of the discharge tube, and that further the length of the discharge tube between 0.8 and 2 m, while the length of the caecum-shaped pipe section dasC, 005 - O, l times the length of the discharge tube and the volume of the piston is 0.5 - 4 times the volume of the discharge tube.

Furthermore, it is extremely practical that the discharge tube is U-shaped or folded U-shape, i.e. at least 4 parallel, meander-like connected pipes.

Since there is no pressure equalization pipe, it is also possible that the Discharge tube is straight or elongated in shape. A facility designed in this way is particularly inexpensive and easy to manufacture.

A considerable simplification of the production and therefore also cheaper The device is also effected by placing the electrodes over olybdenum platelets are led out of the piston, since in such an embodiment of the invention Setup eliminates the otherwise necessary horsetail.

Exemplary embodiments of the subject matter of the invention are shown in the drawing reproduced in a simplified manner.

FIG. 1 shows a device according to the invention for generating ultraviolet radiation with a U-shaped bent discharge tube, Figure 2 a The basic circuit arrangement describing the power supply of the device according to FIG. 1, and FIG. 3 shows the relative UV yield I of the device according to the invention Fig. 1 as a function of noble gas pressure p.

In Fig. 1, a U-shaped bent discharge tube 1 is shown, a cylindrical piston 2 or 2 'is attached to each of the two ends, In each of which there is an electrode 3 or 3 ', i.e. via feedthroughs 4 respectively.

4 'is directed to the outside. In the middle of the bend of the Discharge tube 1 is a caecum-shaped pipe section 5, which serves to hold mercury (not shown in the figure). The discharge tube 1 including the two pistons 2 and 2 'as well as the caecum-shaped one Tube piece 5 consists of quartz glass, which is doped so that the ozone-generating Mercury lines 185 and 194 nm are absorbed however the germicidal line 254 nm is passed through with practically no absorption losses. The electric Feedthroughs 4,4 'are lolybdenum plates which are inserted into the quartz glass of the flasks 2, 2' are pressed in. 6 with a wire contacting the discharge tube 1 is referred to, which after application of impulses of approx. 20 kV, the ignition of the ready for operation Discharge tube 1 causes. This wire can also be used as a discharge tube holder be used.

The discharge tube 1 is approximately round in cross section and has preferably between 8 and 15 mm inside diameter and between 0.8 and 2 m lying length. The two pistons 2, 2 'preferably have one 1 - 4 times larger inside diameter than the discharge tube 1 and have a 0.5-4 times the volume of the discharge tube 1. The appendix-shaped Pipe section 5 is preferably between 10 and 50 mm long and has an inner diameter which is 0> 3 - l times the inner diameter of the discharge tube 1.

The shape and structure of the electrodes 3> 3 'are essentially the same the shape and structure of the thermoemissive cathode according to DT-OS 21433 557, in particular Explanations for FIG. 4. In addition, however, using Nickel powder and <Ba> (Ba, Ca, Sr) carbonate-made oxide cathodes or a tungsten, molybdenum or tantalum sintered bodies and barium or a rare earth metal containing dispenser cathodes very well proven.

The power supply of the device according to the invention is the circuit arrangement according to FIG. 2. In this arrangement, an electrode heating transformer T is on the primary side connected to a 220 V AC voltage source. Part of the secondary winding is used for heating the electrode 3, another part for heating the electrode 3 '. An ignition circuit is parallel to two power supplies for the two electrodes 3 and 3 ' ZS placed, which supplies the wire 6 with ignition pulses of approx. 20 kV. The the electrode 3 with power supplying a secondary winding of the heating transformer T is over a current-limiting choke L and a switch S with one pole of the voltage source connected, while the other secondary winding supplying current to the electrode 3 ' of the heating transformer T short-circuited with the other pole of the voltage source is. This arrangement allows the device according to the invention to be simple Operate media without the usual use of rectifiers.

Argon, krypton and / or xenon as well as mercury, which is housed in excess in liquid form in the caecum-shaped pipe section 5 is used. The mercury temperature and therefore the mercury pressure will be by heating the appendix-shaped ear piece to temperatures between 48 and 650 C set.

According to FIG. 3, where the UV yield of the device according to the invention in the range of wavelength 254 nm depending on from the noble gas pressure of the filling gas used is applied in Torr, it can be seen that the UV yield of UV lamps according to the invention in the range between 0.01 and 0.5 Torr with argon, Krypton or xenon fillings are over 50 Z of the maximum UV yield and therefore in this pressure range the desired high radiation intensity at the wavelength 254 nm is easily achieved. In addition, it has proven to be very useful set the xenon pressure between 0.04 and 0.1 Torr, since xenon is in this pressure range especially with regard to the ionization voltage during electrical discharge has similar properties to mercury at 550 C, so the lamp after cold ignition with an extremely simple circuit to high currents very quickly can be booted up.

All curves of FIG. 3 were taken on a discharge tube of approximately 10 mm Inside diameter, with a mercury pressure corresponding to a condensate temperature of 550 C. and a current density of 5 A / cm2.

Instead of limiting the current to just 5 A / cm2, it is depending on the shape and dimensions of the lamps according to the invention, the current density is expedient between 3 and 10 A / cm2 and the arc voltage between 0.3 and 1.2 V / cm2.

several devices according to the invention have been in use for many hundreds Hours, compared to the well-known DC-operated UV lamps according to the DT-OS en 2412 997 and 21433 557 less aging has occurred.

The efficiency in the range of the germicidal wavelength 254 nm ( UV-C) is around 25% and is around three times as high as the efficiency of AC operated high pressure mercury lamps.

Claims (11)

Claims X device for generating ultraviolet radiation with high radiation intensity, at which the radiation in a UV radiation permeable and a discharge tube with a mercury-noble as filling between 4 and 20 mm lying inside diameter through a wall-stabilized, between two Electrodes occurring gas discharge, at a pressure of mercury between 5.10-3 and 5.10 Torr, a pressure of the noble gas between 0.01 and 10 Torr and a current density of the discharge current of the gas discharge between 1 and 25 A / cm2 can be generated thermo-emissively is, and wherein the Entladunrsrohr at both ends with a tubular Piston is connected, in which one of the two electrodes is housed, characterized in that two therrnoemissive, in terms of geometric Dimensions, structure and material composition largely identical and electrodes (3, 3 ') which can be charged with alternating current are present, and that as Noble gas argon, krypton and / or xenon with one in the operating state of the device between 0.01 and 0.5 Torr lying gas pressure (p) are provided. 2. Device according to claim 1, characterized in that as Electrodes made using nickel powder and (Ba, Ca, Sr) carbonate Oxide cathodes or a tungsten, r.olybdAn or tantalum sintered body and barium or a rare earth metal containing dispenser cathodes are provided. 3. Device according to claim 2, characterized in that the pressure of the xenon is between 0.04 and 0.1 Torr. 4. Device according to one of claims 1 - 3, characterized in that that the electrodes (3,3 ') are led out of the piston (2,2') via molybdenum plates (4,4 ') are. 5. Device according to one of claims 1 - 4, characterized in that that both pistons (2.2 ') in terms of their geometric dimensions and their aterialzusam are identical and made of the same material as the discharge tube (1) exist. 6. Device according to claim 5, characterized in that the discharge tube (1) and the two bulbs (2,2 ') consist of doped quartz glass, the doping is such that the lines at 185 and 194 nm are almost completely absorbed and the line at 254 nm is transmitted with almost no loss. 7. Device according to one of claims 1 - 3, characterized in that that on the discharge tube an appendix-shaped, to absorb the condensed mercury certain pipe section (5) is provided, the temperature of which is between 48 and 65 ° C is adjustable. 8. Device according to claim 7, characterized in that the inner diameter of the discharge tube (1) is between 8 and 15 mm, whereas the diameter is of the caudal-shaped pipe section (5) 0.3 - l times and the diameter of the Piston (4,4 ') 1 - 4 times the diameter knife of the discharge tube (1) and that the length of the discharge tube (1) is between 0.8 and 2 m, while the length of the blir.darsn-shaped ear piece (5) is 0.005 - O, l times the length of the discharge tube (1) and the volume of the piston (2.2 ') 0.5-4 times the volume of the discharge tube (1). 9. Device according to one of claims 1 - 3, characterized in that that the discharge tube (1) has a U-shape or folded U-shape. 10. Device according to one of claims 1 - 3, characterized in that that the discharge tube (1) is straight or elongated in shape. 11. Device according to one of claims 1 - 3, characterized in that that the discharge tube (1) touching from the outside, with impulses of about 20 kV loadable wire (6) is provided.