DE4016555C1 - Cooled UV-low pressure emitter esp. mercury vapour lamp - has extended discharge tube sub-divided into several longitudinal sections parallel to one another and bonded by means of elbows - Google Patents

Abstract

Cooled UV - low pressure emitter, esp. mercury vapour - low pressure lamp, has a longitudinally extended discharge tube (I) which, in cross-section, is formed with a part of its wall adjacent to a central condenser tube (II), or an integral component of (II), (II) running parallel to (I), and is provided with connections for the inlet and outlet of a coolant. The improvement is that (I) is subdivided into several longitudinal sections (3a,3b,3c and 3d), which surround (II) symmetrically and parallel to one another, and are bonded together by mean of elbows. The sections (3a,3b,3c and 3d) have half-moon- or crescent-shaped cross-sections, whereby they fit their shorter wall sections (3e) level and crack-free on (II), or form an integral component of (II). ADVANTAGE - The performance of the emitter is greatly increased, while avoiding losses and maintaining the output-max. for UV-radiation.

Description

The invention relates to a cooled ultraviolet (UV) never pressure radiator, in particular a mercury vapor low Pressure lamp, according to the preamble of claim 1.

Such radiators are u. a. in irradiation apparatus for Generate photochemical reactions or reaction products used, as is shown in DE-PS 27 33 344 and 34 22 553 is posed and described.

The radiator protrudes into a reaction vessel, at the inside of which a thin film of liquid from top to bottom flows. Thickness and speed of the liquid film can with the help of a rotating body equipped with wiping elements are influenced, the wiping elements simultaneously the Be inside wall of the reaction vessel of any deposits free. The UV radiation in particular in the liquid film of dissolved, organically bound carbon photoche mix converted into carbon dioxide using a carrier gas driven out and then quantified. Combined If you use a chromatograph to do this, you can go through a correlation of the measurement results also quanti tative statements about individual carbon compounds in the Make liquid.

The photochemical implementation in the radiation equipment is depending on the intensity of UV radiation. The book "Ultravio lette rays ", ed. Jürgen Kiefer, publishing house de Gruyter, Ber lin, New York, 1976, Fig.3.11 on page 62 can be seen that the light output for low-pressure mercury lamps a vapor pressure of approximately 0.1 mm Hg column in the discharge tube has a maximum. Since the vapor pressure in turn depends on the tem temperature of the discharge tube (see page 70), be  this means that care must be taken to ensure that the discharge tube at a temperature, e.g. B. is kept at about 40 ° C at the maximum yield of UV radiation results.

DE 28 25 018 C2 describes a low pressure of mercury vapor lamp for disinfection or sterilization using ultra violet (UV) radiation known, the discharge tube a has an elongated-flat cross section. Along the two Two cooling sides extend from the narrow sides of the discharge tube pipes fed with a cooling gas or cooling water will. This will emit the ratio of UV radiation render surface to discharge volume compared to a Discharge tube with round cross section improved. So that leaves however, under the aforementioned pressure and temperature conditions not achieve stable long-term operation; the plasma in Form of a "board" flickers.

In the older, not prepublished DE 39 13 519 A1 proposed a UV lighting system, the discharge area consists of two concentric tubes. On the inside a cooling jacket is provided for this double-walled tube, through which a liquid circulates. This will also the ratio of tube surface area to discharge volume increased over a circular discharge tube at the same time improve the cooling option. But also with one The resulting annular plasma can be created at low pressure no stable area, maximum yield for UV radiation Achieve gender operation of the discharge vessel.

The object of the invention is a UV low-pressure lamp to combine the generic type with cooling ren that largely lossless and maintaining of the maximum yield for UV radiation is the power of the radiator can be increased significantly.  

This task is characterized by the characteristics of An spell 1 solved. The subclaims related to this include ten advantageous refinements and developments of these Solution.

With the invention, the power of the radiator - and thus also the yield of UV radiation by more than three times the ge be increased. This in turn has a corresponding shortening result of the irradiation and measuring times; d. H. the Ge speed with which the liquid film on the inner wall of the radiation vessel can be increased. For this purpose, the speed of rotation of the body at which the Wiper elements are arranged helically, increased. The higher radiation intensity also guarantees a full constant implementation of relatively stable carbon ver bonds.

Through the cooling pipe or the coolant flowing in it, normally water, although UV radiation is used partially absorbed. However, since this tube was being irradiated on the lenden liquid film side is arranged, ent there is no immediate, the photochemical implementation impairing radiation loss.

Exemplary embodiments of the invention are described below of the drawings:

Fig. 1 shows a cross section through an irradiation apparatus, which is equipped with a UV low pressure radiator cooled according to the invention.

Fig. 2 shows in longitudinal section the lower end of Strah coupler of FIG. 1.

Fig. 3 shows in cross section a variant of the inventive cooled UV low-pressure lamp.

The irradiation apparatus comprises a stationary, rotationally symmetrical reaction vessel 1 , on the inner wall 1 a of which the measurement sample flows down in the form of a thin liquid film. The test sample contains, among other things, dissolved organic carbon compounds that are to be determined. In the reaction vessel 1 and at a distance from its inner wall 1 a is a hollow cylindrical, UV-transparent Rotati on body 2 , which can be set in rotation about its longitudinal axis 2 c by an external drive. The rotary body 2 is equipped with blind hole-like guides 2 a for receiving rod-shaped wiping elements 2 b. The elements 2 b are arranged in the manner of a spiral along the periphery of the rotary body 2 . The rotation of the Rotationskör pers 2 , the elements 2 b are pressed due to the centrifugal forces against the inner wall 1 a of the reaction vessel 1 and set zen the measuring liquid in rotation, so that he imagined thin film forms. Depending on the sense of rotation of the rotary body 2 of the Ele due to the helical arrangement of elements 2, the flow rate b of the film from top to bottom accelerated or delayed. For the rest, reference is made to the patents cited at the beginning with regard to the general structure and functioning of the radiation apparatus.

As can further be seen from FIG. 1, an elongated mercury discharge tube in the form of four longitudinal tube sections 3 a, 3 b, 3 c, 3 d protrudes into the rotary body 2 , which run parallel to one another and by means of tube bends constricted in cross section 3 f ( Fig. 2) are interconnected. The electrical connections are located at two end sections (not visible) running upwards from the vessel 1 . The Rohrab sections 3 a, 3 b, 3 c, 3 d are distributed symmetrically around a central cooling tube 4 ; they have crescent-shaped cross-sections where, with their shorter wall sections 3 e facing the longitudinal axis 2 c, they rest flat and without gaps on the central cooling tube 4 . The cooling tube 4 is closed at its lower end by a rounded bottom 4 a; inside there are a central tube 4 b for the coolant supply, which is led down to just above the bottom 4 a with its mouth. Another, the cooling tube 4 penetrating tube 4 c is used to remove carrier gas, for. B. nitrogen, and expelled CO ₂ . The tube 4 is also led upwards out of the vessel 1 for the removal of the coolant. The pipe sections 3 a, b, c, d each have a length of approximately 250 mm with an outer diameter of the longer wall sections of 14 mm and a wall thickness of 1 mm. Only the outer, arcuate sections pointing to the periphery need to be transparent to UV radiation. Instead of the arrangement of a separa th cooling tube 4 , it is also possible to cut the four inner Bogenab 3 e z. B. with the help of a laser to a common cooling tube. The required cooling capacity is set by adjusting the cooling water throughput through the pipe 4 , if necessary also by an additional precooling of the cooling water. The setting is made so that the pipe sections 3 a, b, c, d on their periphery facing the outer wall assume a temperature of about 35 ° C.

In this way, an mercury vapor lamp achieves an optimal yield of UV radiation with a wavelength of 185 nm, accompanied by the 254 nm line. With an electrical input power of 110 to 120 watts, up to approx. 80 watts are converted into pure UV radiation power. This UV radiation of the discharge tube 3 a, b, c, d causes in the liquid film along the inner wall 1 a intensive, photochemical reactions in which, among other things, CO ₂ is generated, which is expelled and measured with a carrier gas. The swirling of the liquid film by the wiping elements 2 b favors these processes.

Fig. 3 shows in cross section a variant of the UV low-pressure lamp according to the invention, in which the discharge tube forms an integral part of the cooling tube. The discharge tube consists of two elongated, cross-sectionally crescent-shaped sections 5 a, 5 b made of UV-permeable quartz glass, which are connected at their lower end (not visible) by a pipe bend. The electrical connections are at the upper ends. The sections 5 a, 5 b are welded together along their sickle tips 5 c, 5 d so that the shorter sickle arches 6 a, 6 b enclose a cross-sectionally sen-shaped space 6 , which is closed at its lower end and as a cooling tube for the sections 5 a, 5 b serves. The coolant is supplied via a tube 6 c, which protrudes centrally into the space 6 from above and opens out just above its lower, closed end. The coolant is removed at the top of room 6 . From this embodiment is particularly suitable for irradiation equipment or reaction vessels with relatively narrow cross sections.

Claims (3)

1. Cooled UV low-pressure lamp, in particular mercury vapor low-pressure lamp, with an elongated discharge tube which, viewed in cross section, adjoins part of its wall with a central cooling tube or forms an integral part of this central cooling tube, the cooling tube being parallel to that Discharge tube runs and is provided with connections for the supply and discharge of a coolant, characterized in that
that the discharge tube is divided into several longitudinal tube sections ( 3 a, 3 b, 3 c, 3 d) which surround the central cooling tube ( 4 ) parallel to one another and symmetrically and are connected to one another by means of tube bends ( 3 f), and
that the longitudinal tube sections ( 3 a, 3 b, 3 c, 3 d) have crescent-shaped or si cheliform cross-sections, with their shorter wall sections ( 3 e) lying flat and gap-free on the central cooling tube ( 4 ) or an integral component of the central cooling pipe. 2. UV low-pressure lamp according to claim 1, characterized in that the pipe bends ( 3 f) encompass the front ends of the cooling tube ( 4 ), and that the cooling tube ( 4 ) is closed on one side on an end face ( 4 a), the connection ( 4 b) for the coolant supply through the interior of the cooling tube ( 4 ) and opens close to the closed end ( 4 a). 3. UV low-pressure lamp according to claim 1, characterized in
that the discharge tube consists of two cross-section sickle-shaped longitudinal sections ( 5 a, 5 b), which are connected at their lower ends, and
that the sections ( 5 a, 5 b) are welded together along their sickle tips ( 5 c, 5 d), so that the shorter sickle arches ( 6 a, 6 b) form a cooling tube ( 6 ) with a lenticular cross section.