WO1996031902A1

WO1996031902A1 - Low-pressure mercury vapour discharge lamp

Info

Publication number: WO1996031902A1
Application number: PCT/DE1996/000647
Authority: WO
Inventors: Horst Wedekamp
Original assignee: Wedeco Umwelttechnologie Wasser-Boden-Luft Gmbh
Priority date: 1995-04-05
Filing date: 1996-04-04
Publication date: 1996-10-10
Also published as: DE19613468A1; JPH10505197A; EP0764341A1

Abstract

A low-pressure mercury vapour discharge lamp to generate u/v radiation in the wavelength range from some 170 to 280 nm for the irradiation of liquid or gaseous media and/or surfaces. The low pressure mercury vapour discharge lamp has a lamp tube (12) on the inner wall (14) of which there is at least one metal filling (32) forming an amalgam. Said metal filling is on the inside of the lamp tube at at least one point between the electrodes of the lamp, and the outer wall of the lamp tube is in mechanical contact with a cooler (46) at this point.

Description

Low-pressure mercury discharge track

The invention relates to a mercury low-pressure discharge sheet according to the preamble of patent claim 1.

Low-pressure mercury discharge lamps are generally used to disinfect water or air. In addition, there are also applications in the UV irradiation of surfaces. The low-pressure mercury discharge lamps generate UV radiation with a line spectrum with an intense emission line of wavelength 253.7 nm and considerably weaker emission lines of wavelengths below 200 nm with a maximum at around 185 nm and 194 nm.

The short-wave portion of UV radiation in the wavelength range of less than 200 nm is required for various photochemical processes, for example the emission line of approximately 185 nm for generating ozone from oxygen and for curing lacquers and adhesives. Even in the treatment of ultrapure water, which is required, for example, in the electronics industry for the production and manufacture of semiconductors, this short-wave radiation enables photo-oxidative degradation of pollutants. In known low-pressure mercury discharge lamps, however, the percentage of short-wave radiation below 200 nm is relatively low compared to the share of radiation in the range of 254 nm, and in conventional low-pressure mercury discharge lamps, this share of short-wave UV radiation of 185 nm - based on the proportion of 254 nm radiation - only at a maximum of about 10%.

At a certain mercury vapor pressure, mercury low-pressure discharge lamps have an optimal degree of efficiency, based on the radiation power at 254 nm. The optimum vapor pressure, depending on the lamp tube cross section, is usually achieved with operating currents in the range from approximately 0.1 ampere to 1 ampere.

In order to achieve a higher lamp output, it is already known that the operating current can be increased if an amalgam-forming metal filling is arranged within the lamp tube of the low-pressure mercury discharge lamp. The amalgam is known to be a mercury alloy which, for. B. consists of mercury and indium. If such a metal filling is provided on the inside of the lamp tube of the low-pressure mercury discharge lamp between the electrodes or incandescent filaments in the region of the discharge path, the low-pressure mercury discharge lamp can be operated with a larger operating current of approximately 2 to 3 amperes.

In practice it has been shown that both when using the metal filling mentioned, an increase in short-wave UV radiation in the range below 200 nm cannot be achieved at the same time as UV radiation at 254 nm. Although one could think of increasing the operating current even further when using the metal filling, it has been shown that no increase in the radiation power can be achieved in this way.

The invention has for its object to improve a mercury low-pressure discharge lamp of the type mentioned in the preamble of claim 1 in such a way that, despite the circumstances described above, a substantial increase in short-wave UV radiation in the range from 170 to 200 nm and above all the emission line of 185 nm compared to UV radiation of 254 nm is reached.

This object is achieved in the invention by the features specified in the characterizing part of patent claim 1.

The invention therefore presupposes the use of the metal filling which is known per se, but in a novel manner it is provided that the outer wall of the lamp tube has mechanical contact at the point where the metal filling is on the inner wall of the lamp tube or a mechanical contact is made with a heat sink.

This measure results in cooling at the point in question with the effect that the mercury low-pressure discharge lamp can be operated with a substantially higher operating current. As a result of this higher operating current, a surprisingly significant increase in short-wave UV radiation in the range from 170 to 200 nm and in particular is desired of 185 nm compared to UV radiation of 254 nm.

The invention is based on the knowledge that the operating vapor pressure of the mercury of the low-pressure mercury discharge lamp depends on the wall temperature of the lamp tube and on the electrical operating parameters. For this reason, in the known mercury low-pressure discharge lamps, the possibility of increasing the operating current mentioned above does not lead to an increase in the radiation power either because the lamp tube of the low-pressure mercury discharge lamp then becomes too hot and the optimum operating vapor pressure of the mercury does not occur. By contrast, the cooling provided in the invention allows the mercury low-pressure discharge lamp to be operated with a higher operating current, with the result that the short-wave UV radiation rises significantly in the range from 170 to 200 nm, because cooling prevents it from being prevented the operating vapor pressure in the lamp tube rises and exceeds saturation.

Experiments have confirmed by measurements of a mercury low-pressure discharge lamp according to the invention that the percentage of short-wave UV radiation of approximately 185 nm - based on the radiation fraction of 254 nm - can be increased to values of 90%. This is a multiple of what was possible with previous low-pressure mercury discharge lamps. With the new low-pressure mercury discharge lamps, for example, a significantly higher photo-lytic or photo-oxidative effect can be achieved, which is particularly advantageous in the treatment of ultrapure water, for example. An expedient embodiment of the invention provides that the metal filling is or are arranged within one or more radially outward bulges of the lamp tube, and that the bulges are at least partially in contact with a heat sink.

In this further development of the invention, the metal fillings are no longer arranged on the smooth inner wall of the lamp tube as before, rather the lamp tube has radially outwardly directed bulges in the form of dents which form depressions in the manner of a crucible, and within these bulges are the metal fillings. The bulges are at least partially in contact with a heat sink, which in turn causes cooling, which enables the substantial increase in the operating current and thus the significant increase in the short-wave UV radiation in the range from 170 to 200 nm.

In order to effect the cooling provided as an important measure in the invention, it is provided in a further expedient embodiment of the invention that the metal filling is arranged in the immediate vicinity of the bulges mentioned above. It is crucial here that the metal fillings are arranged so close to the bulges mentioned that they lie in the effective range of the cooling zone and that significant cooling is still achieved.

According to another advantageous development of the invention, the low-pressure mercury discharge lamp is arranged in a cladding tube which is transparent to UV radiation in such a way that the bulges of the lamp tube are at least are at least partially in contact with the outer cladding tube, the cladding tube forming the heat sink.

This embodiment is advantageous, for example, when the low-pressure mercury discharge lamp is designed with the outer cladding tube as a submerged emitter, the cladding tube being surrounded by a liquid medium. This liquid medium then advantageously supports the cooling.

Within the scope of the invention, it is also possible, according to a further expedient embodiment of the invention, for the above-mentioned cladding tube to have radially inward indentations at the locations of the metal fillings, which are in contact with the aforementioned locations of the metal fillings, the cladding tube forming the heat sink . It is crucial that the metal fillings are in contact with the outer cladding tube, which contributes to cooling.

The lamp tube of the low-pressure mercury discharge lamp expediently has a cross section of at least 0.5 cm and at most 12 cm, preferably about 3 cm.

In a further embodiment of the invention, the lamp tube has a cross section which is at least 30% smaller in the region of its discharge path than at the two outer ends in the region of the electrodes. At the two outer ends, the lamp tube thus has sections with a larger cross section than in the middle in the actual discharge area.

In a further embodiment of the invention, the metal fillings or the bulges of the lamp tube are located or the aforementioned indentations of the cladding tube in the region of the electrodes, that is to say in the region of the ends with the larger cross sections.

Another variant provides that the metal fillings are located in the region of the discharge path of the lamp tube, that is to say in the region with the smaller cross section. A metal filling is preferably arranged on each side - adjacent to the areas with the larger cross section.

The invention can also be used to advantage if the lamp tube has a flat, elongated cross section deviating from the circular shape with two broad sides (radiation sides) and two narrow sides and is designed as a flat radiator known per se. The bulges or the metal fillings are then located on at least one narrow side of the flat radiator.

Further expedient refinements of the invention result from the subclaims.

The invention is explained in more detail below on the basis of the exemplary embodiments shown in the drawing. Show it:

Fig. 1-9 different embodiments of a mercury low-pressure discharge lamp, and

10 shows a graphical representation of the portions of the wavelengths or emission lines at approximately 185 nm and approximately 254 nm of the UV radiation generated. lung.

1 shows a low-pressure mercury discharge lamp 10 with a lamp tube 12. The lamp tube 12 has an inner wall 14 and an outer wall 28. At the ends there are in each case a base 22 with electrical connecting pins 24, which in connection with the inside of the Electrodes 20 (incandescent filaments) are provided in the lamp tube.

A metal filling 32 is firmly attached to the inner wall 14 of the lamp tube 12 in the area between the electrodes 20, and at the opposite point the outer wall 28 of the lamp tube 12 is in contact with a heat sink 46, which is formed, for example, by a heat sink can. The heat sink 46 causes cooling in the area of the metal filling 32, so that the mercury low-pressure discharge lamp 10 can be operated with a comparatively high operating current of greater than 2.5 amperes. This results in a decisive increase in short-wave UV radiation in the range from 170 nm to 200 nm, compared to UV radiation of approximately 254 nm.

The illustration in FIG. 2 shows a low-pressure mercury discharge lamp 10, in which two metal fillings 32 are provided. The lamp tube 12 has two corresponding radially outward bulges 30 in which the metal fillings 32 are located. On the outer wall 28 of the lamp tube 12, these bulges 30 are in contact with the heat sinks 46.

A variant of a lamp tube with a bulge 30 is also shown in FIG. tion with the heat sink 46 is, however, the metal filling 32 is not in the bulge 30 itself, but in the immediate vicinity thereof. The metal filling 32 is still in the effective range of the heat sink 46, so that cooling can also take place here.

In the exemplary embodiment shown in FIG. 4, the low-pressure mercury discharge lamp 10 is designed as a submerged emitter, because the lamp tube 12 is located within a cladding tube 26 which is transparent to UV radiation. The bulge 30, in which the metal filling 32 is located, is in contact with the cladding tube 26, which thus forms the heat sink. Immersion heaters are usually used to irradiate liquids, which then surround the cladding tube 26, as a result of which the cladding tube 26 is particularly suitable for performing the function of a heat sink.

The illustration in FIG. 5 also shows a low-pressure mercury discharge lamp 10 with an outer cladding tube 26. This cladding tube 26 has an indentation 44 which is in contact with the outer wall 28 of the inner lamp tube 12, specifically at the point where on the inner wall the metal filling 32 is arranged. This is here directly on the inner wall 14 of the lamp tube 12, d. that is, unlike in FIG. 4, no bulge is provided here; the bulge is practically replaced by the indentation 44.

6 shows another embodiment in partial representation, only one end of the low-pressure mercury discharge lamp 10 being shown for reasons of space. The lamp tube 12 has on the two Ends in the area of the electrodes 20 a larger cross section than in the area of the actual discharge gap 18, that is to say in the central area. The cross section in the central region of the discharge gap 18 is at least 30% smaller than in the region of the ends 16 with the larger cross section.

The at least one metal filling 32 is arranged in the region of one end 16 with the larger cross section on the inner wall 14 of the lamp tube 12 and is in turn connected to a heat sink 46, which here has a radially inward indentation in the region of the metal filling 32. The heat sink 46 could thus also be formed by the cladding tube 26 shown in FIG. 5.

7 also shows a low-pressure mercury discharge lamp 10, in which the ends of the lamp tube 12 have a larger cross section 16 than the discharge path 18. The difference from Fig. 6 is that the metal filling 32 is arranged in the bulge 30, and that the heat sink 46 is flat.

The exemplary embodiment according to FIG. 8 also shows a lamp tube 12 in which the ends 16 have an enlarged cross section. However, the metal filling 32 is not arranged in the region of the enlarged cross section 16, but in the region of the discharge path 18 in the bulge 30, which is in contact with the heat sink 46.

Finally, FIG. 9 shows, as a further exemplary embodiment, in a partial representation a flat radiator 34 in which the lamp tube has two broad sides 36 and two has narrow sides 38. The bulge 30 for receiving a metal filling is located on a narrow side 38 of the flat radiator 34. This bulge is - which is not shown in FIG. 9 - also in contact with a heat sink or with a cladding tube.

10 shows a graphical representation of the wavelengths or emission lines of the UV radiation generated with a mercury low-pressure discharge lamp according to the invention. The emission lines of the short-wave UV radiation 40 with a wavelength of approximately 185 n and the emission radiation 42 with a wavelength of approximately 254 nm are particularly striking.

As can be seen, the short-wave portion 40 of the radiation of 185 nm is almost 90% of the portion of the radiation 42 of 254 nm. Such a high percentage of the short-wave radiation 40 of 185 nm is compared to the radiation 42 of 254 nm completely surprising and could not be achieved so far.

Claims

Patent claims

1. Low-pressure mercury discharge lamp (10) with a lamp tube (12) and with at least one metal filling (32) forming amalgam therein on the inner wall (14), for generating UV radiation in the wavelength range of approximately 170 nm to 280 nm for the irradiation of liquid or gaseous media and / or of surfaces, characterized in that the metal filling (32) between the electrodes (20) of the low-pressure mercury discharge lamp (10) on the inner wall (14 ) of the lamp tube (12) is arranged, and that the outer wall (28) of the area of the lamp tube (12) corresponding to this point of the inner wall (14) is in contact or in contact with a heat sink (26; 46).

2. Mercury low-pressure discharge lamp (10) according to claim 1, characterized in that the metal filling (32) is arranged within one or more radially outward bulges (30) of the lamp tube (12), and that the Bulges (30) are at least partially in contact with a heat sink (26; 46).

3. Low-pressure mercury discharge lamp (10) after Claim 1, characterized in that the metal filling (32) is arranged in the immediate vicinity of one or more radially outwardly directed bulges (30) of the lamp tube (12), and that the bulges (30) are at least partially in contact with a heat sink (26; 46) stand.

4. mercury low-pressure discharge lamp (10) according to one or more of the preceding claims 1-3, da¬ characterized in that the mercury low-pressure discharge lamp (10) is arranged in a sheath tube (26) permeable to UV radiation, that the bulges (30) of the lamp tube (12) are at least partially in contact with the outer cladding tube (26), and that the cladding tube (26) forms the heat sink.

5. Low-pressure mercury discharge lamp (10) according to claim 1, characterized in that the low-pressure mercury discharge lamp (10) is arranged in a sheath tube (26) which is transparent to UV radiation, that the sheath tube (26) at the points the metal filling (32) has radially inward indentations (44) which are in contact with the said locations of the metal filling (32), the cladding tube (26) forming the heat sink.

6. Low-pressure mercury discharge lamp (10) according to one or more of the preceding claims 1-5, characterized in that the lamp tube (12) has a cross section of at least 0.5 cr and a maximum of 12 αmr .

7. mercury low-pressure discharge lamp (10) according to one or more of the preceding claims 1-6, da¬ characterized in that the lamp tube (12) in the area its discharge path (18) has a cross section which is at least 30% smaller than at the two outer ends (16) in the region of the electrodes (20).

8. low-pressure mercury discharge lamp (10) according to one or more of the preceding claims 1-7, da¬ characterized in that the operating current through the low-pressure mercury discharge lamp (10) is greater than 2.5 amps.

9. mercury low-pressure discharge lamp (10) according to one or more of the preceding claims 1-8, da¬ characterized in that the metal fillings (32) or the bulges (30) of the lamp tube (12) or the indentations (44) of the cladding tube (26) are arranged in the region of the larger lamp tube cross sections (16).

10. mercury low-pressure discharge lamp (10) according to one or more of the preceding claims 1-9, da¬ characterized in that the lamp tube (12) deviates from the circular flat oblong cross-section with two wide sides (36) (radiation sides) and has two narrow sides (38) and is designed as a flat radiator (34) known per se.

11. Low-pressure mercury discharge lamp (10) according to claim 10, characterized in that the metal fillings (32) or the bulges (30) are located on at least one narrow side (38) of the flat radiator (34).