DE2752593C2 - - Google Patents

Description

The invention is based on a radiation source according to the preamble of claim 1.

Here, the invention relates to a prior art of radiation sources, such as that described in DE-OS 24 33 557 is described. The known radiation sources can appropriate training of their electrodes with alternating current are operated, but are usually for direct current surely drove. You need one each trained as a pipe pressure equalization room. In the discharge can be electro do not avoid phoretic processes. This is done accordingly an uneven radiation over the entire surface of the Discharge space and premature aging of the beam occurs source.

DE-AS 21 50 740 is a radiation source of high intensity known in the ultraviolet, in the case of a mercury containing and with one of the gases helium, neon, argon, Xenon or krypton-filled pipe emit a remote emission UV is stimulated. This emission is generated in a on the  Mounted the inside surface of a piston surrounding the tube Fluorescent layer in the visible and near ultraviolet high intensity radiation. This is a comparatively high partial pressure of the one in the pipe Gases required.

From DE-AS 11 98 452 it is also known to control of the mercury vapor pressure and for the condensation of the mercury a mercury vapor discharge lamp a dome-shaped bulged, melted onto the discharge bulb of the lamp zenes pipe piece to provide. This piece of pipe is on a kept relatively low temperature, so in the with an inert gas from a comparatively high partial pressure-filled discharge bulb optimal temperature conditions for a low pressure mercury vapor discharge. Electrophoretic processes in the discharge can be However, do not avoid it, so that an uneven radiation takes place over the entire surface of the discharge space and premature aging of the radiation source occurs.

It is an object of the invention to provide a radiation source to specify the type with which with simple constructive Execution especially at the wavelength 254 nm high radiation intensity and uniform radiation is achieved over the entire surface, and which ones moreover through long service life and great effectiveness degree.

This task is combined with the characteristics of the waiter Concept according to the characterizing part of claim 1 solved.

The radiation source according to the invention is characterized by long service life and high efficiency. Due suitable adjustment of the noble gas pressure is one with the hitherto usual direct current operated radiation sources comparable radiation intensity achieved, whereby because of  Lack of electrophoretic processes also a uniform Radiation over the entire surface of the discharge tube is achieved. It is also advantageous that the supply the radiation source from the mains with a ballast without Interposition of a rectifier can take place, and that due to the appendix shaped tube of steam pressure of the mercury and thus that of the radiation source emitted radiation intensity particularly easily regulated can be. A pressure compensation tube can be omitted.

It is highly recommended to put the pressure of the xenon between 5.3 and 13.3 Pa to choose, because xenon in this pressure area similar in terms of discharge behavior Shafts like mercury at 55 ° C and the invention radiation source therefore cold and / or without standby Circuit started and driven up extremely quickly can.

For use in the food and packaging industry it is particularly favorable that the discharge tube and the two pistons made of doped quartz glass, the Doping is such that it lines at 185 and 194 nm are almost completely absorbed and the line at 254 nm is transmitted almost loss-free, since now through the lines caused unwanted ozonization the air is almost completely suppressed, whereas the desired germs caused by the transmitted line killing can be fully exploited.

Since the pressure compensation tube is no longer necessary, the Ent to form the charge tube straight or straight. Such ge Designed radiation sources are particularly inexpensive and one to manufacture.

In the drawing is an embodiment of the invention reproduced in simplified form.  It shows

Fig. 1 shows a radiation source according to the invention for generating ultraviolet radiation with a U-shaped bent discharge tube,

Fig. 2 is a power supply of the radiation source shown in FIG. 1 described basic circuit arrangement, and

Fig. 3 shows the relative UV yield I erfindunsgemäßen the radiation source shown in FIG. 1 as a function of p inert gas pressure.

In Fig. 1, a U-shaped discharge tube 1 is Darge, at the two ends of which a cylindrical piston 2 or 2 'is attached, in each of which an electrode 3 or 3' is located, which is via bushings 4 and 4 'is directed to the outside. In the middle of the bending point of the discharge tube 1 there is an appendix-shaped tube piece 5 , which serves to receive mercury, not shown in the figure. The discharge tube 1 , finally, the two pistons 2 and 2 ' as well as the blind-shaped tubular piece 5 is made of quartz glass, which is doped so that the ozone-generating mercury lines 185 and 194 nm are absorbed, but the germicidal line 254 nm is let through practically without absorption losses. The electrical feedthroughs 4, 4 ' are molybdenum platelets, which are pressed into the quartz glass of the pistons 2, 2' . 6 designates a wire which contacts the discharge tube 1 and which, after exposure to pulses of approximately 20 kV, causes the ignition of the ready-to-use discharge tube 1 . This wire can also be used as a discharge tube holder.

The discharge tube 1 is of approximately round cross-section and preferably has an internal diameter of between 8 and 15 mm and a length of between 0.8 and 2 m. The two pistons 2, 2 ' preferably have a 1-4 times larger inner diameter than the discharge tube 1 and have a 0.5-4 times the Ent discharge tube 1 volume. The bladder-shaped pipe section 5 is preferably between 10 and 50 mm long and has an inner diameter which is 0.3-1 times the inner diameter of the discharge tube 1 .

The shape and structure of the electrodes 3, 3 ' corresponds essentially to the shape and structure of the thermoemissive cathode according to DE-OS 24 33 557, in particular explanations for Fig. 4. In addition, however, using nickel powder and ( Ba, Ca, Sr) carbonate-produced oxide cathodes or a wofram, molybdenum or tantalum sintered body and barium or a rare earth metal-containing dispenser cathode have proven very successful.

The power supply of the radiation source according to the invention can be found in the circuit arrangement according to FIG. 2. In this arrangement, an electrode heating transformer T is connected on the primary side to a 220 V AC voltage source. A part of the secondary winding is used to heat the electrode 3 , at the other part to heat the electrode 3 ' . In parallel to two current leads of the two electrodes 3 and 3 ' , an ignition circuit ZS is placed, which supplies the wire 6 with ignition pulses of approximately 20 kV. The electrode 3 with current ver providing a secondary winding of the heating transformer T is connected via a current-limiting choke L and a switch S to one pole of the voltage source, while the electrode 3 ' supplying current to the other secondary winding of the heating transformer T with the other pole Voltage source is short-circuited. With this arrangement, the radiation source according to the invention can be operated with simple means without the otherwise usual use of rectifiers.

Argon, krypton and / or xenon and mercury, which is accommodated in excess in liquid form in the appendix-shaped pipe section 5 , are used as filling gases. The mercury temperature and thus the mercury pressure are set to temperatures between 48 and 65 ° C by heating the section of the appendix.

Referring to FIG. 3, where the UV output of the radiation sources of the invention in the field of wavelength 254 nm in Depending ness from the rare gas pressure of the fill gas used in Pascal on is worn, it can be seen that the UV output of the radiation sources in the range between 1.3 and 66.6 Pa with argon, krypton or xenon fillings above 50% of the maximum UV yield and therefore in this pressure range the desired high radiation intensity at the shaft length 254 nm is easily achieved. In addition, it has proven to be very expedient to set the xenon pressure between 5.3 and 13.3 Pa, since xenon in this pressure range has properties similar to mercury at 55 ° C., in particular with regard to the ionization voltage during electrical discharge that the radiation source can be ramped up very quickly to high currents with an extremely simple circuit after the cold ignition.

All curves of Fig. 3 were measured on a discharge tube of approximately 10 mm inner diameter, at a condensate temperature of 55 ° C corresponding mercury pressure and a current density of 5 A / cm ² .

Instead of limiting the current strength to only 5 A / cm ² , it is advisable, depending on the shape and dimensions of the radiation source, to set the current density between 3 and 10 A / cm ² and the arc voltage between 0.3 and 1.2 V / cm ² .

Several radiation sources have been used for many years len operated a hundred hours, compared with the be known radiation source according to DE-OS 24 33 557 less aging has occurred. The efficiency in the range of the germicidal wavelength 254 nm (UV-C) is about 25% and is about three times as high how the efficiency of AC powered mercury High pressure lamps.

Claims (7)

1. Radiation source for generating ultraviolet radiation with high radiation intensity, in which the radiation in a UV-transparent and with a mercury-noble gas filling discharge tube of an inner diameter between 5 and 20 mm through a wall-stabilized, between two identical, thermo-emissive electrodes Occurring gas discharge at a pressure of mercury between 0.66 and 66.6 Pa and a current density of the discharge current between 1 and 25 A / cm ^{2 can be} generated, the discharge tube being connected at its two ends to a tubular piston, in each of which one of the two electrodes is accommodated, and the two electrodes can be charged with alternating current, characterized in that argon, krypton and / or xenon are provided as the noble gas with a gas pressure (p) in the operating state between 1.33 and 66.6 Pa , and that on the discharge tube an appendix-shaped, for receiving the condensed Qu ecksilbers certain pipe piece ( 5 ) is provided, the temperature of which is adjustable between 48 and 65 ° C. 2. Radiation source according to claim 1, characterized in that that the pressure of the xenon is between 5.3 and 13.3 Pa. 3. Radiation source according to claim 1 or 2, characterized in that both pistons ( 2, 2 ' ) are identical in terms of their geometric dimensions and their material compositions and consist of the same material as the discharge tube ( 1 ). 4. Radiation source according to claim 5, characterized in that the discharge tube ( 1 ) and the two pistons ( 2, 2 ' ) consist 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 transmitted with almost no loss. 5. Radiation source according to claim 1, characterized in that the inside diameter of the discharge tube ( 1 ) is between 8 and 15 mm, whereas, on the other hand, the diameter of the blind-shaped tubular piece ( 5 ) is 0.3-1 times and the diameter of the pistons ( 4, 4 ' ) 1-4 times the diameter 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 appendix-shaped tube section ( 5 ) is 0.005-0, 1 times the length of the discharge tube ( 1 ) and the volume of the pistons ( 2, 2 ' ) is 0.5-4 times the volume of the discharge tube ( 1 ). 6. Radiation source according to one of claims 1-5, characterized in that the discharge tube ( 1 ) has a U-shape or folded U-shape. 7. Radiation source according to one of claims 1-5, characterized in that the discharge tube ( 1 ) is straight or of elongated shape.