NL9302129A - Radiation treatment apparatus suitable for liquid substances or flowing media - Google Patents

Abstract

Apparatus for treating at least partially optically transparent liquid substances or flowing materials by means of light radiation. The apparatus is provided with one or more generally elongate light radiation sources located in an elongate reactor vessel through which the liquid substance or flowing material to be treated is passed during operation. The (or each) elongate light radiation source is pre-fitted in an elongate tube which for this purpose near its ends is provided with fittings for attaching the radiation source and means for the supply leads of the radiation source to be passed through, said tube near its ends further being provided with means for connecting to the tube the supply and the discharge, respectively, for supplying the liquid substance or the flowing material and discharging these, respectively. It is preferable for a tube to have a window on its inside, to which a thin layer of a fluorescent material is applied which when exposed to the radiation emitted by the radiation source will itself radiate radiation within the visible region of the spectrum, and the window is preferably made of a material which transmits said last-mentioned radiation.

Description

Device for the radiation treatment of liquid substances or flowing media

The invention relates to an apparatus for treating at least partially light-radiation-transmitting liquid substances or flowing media by means of light radiation, provided with one or more generally elongated light radiation sources which are located in an elongated reactor vessel where, during operation, the liquid substance to be treated or the flowing medium is passed through it.

Such devices are known in the art and are used for various purposes.

In horticulture, for example, crops are increasingly grown on substrates, rather than in the soil. The plants are sprayed with water, a large part of which drains off again. This water contains food salts, among other things. In order to save the environment and to minimize the purchase of nutrient salts, this waste water is increasingly being reused for irrigation. It is often useful and often also necessary to disinfect this water before reuse to prevent the spread of diseases in a greenhouse or the like. The run-off water can now be disinfected in an installation of the above-described type by exposure to ultraviolet radiation. Very suitable for this are low-pressure mercury lamps that emit light at a wavelength (254 nm) close to the maximum sensitivity of DNA (nucleic acid).

In another application, such devices are used to promote the growth of free floating algae. In that case, a radiation source is used that emits light in the blue part of the spectrum.

Not only liquids, but also gases can be treated in such an establishment. Consider, for example, the disinfection of air or the triggering of a photochemical reaction in gases.

The radiation sources used in such devices are generally constructed as an elongated tube or as an elongated screw coil. These tubes will have to be changed from time to time, on the one hand because the efficiency of the tube itself gradually decreases during operation and, on the other hand, because contamination gradually occurs during operation. Both causes cause the amount of radiation generated by the liquid substance to be treated or the flowing medium to decrease, making it necessary to replace the radiation source.

It has been found in practice that the tubular radiation sources often break and / or become dirty during transport and / or during assembly. If, for example, the wall of the pipe is touched by hand, a deposit may form locally, which then gradually adheres more strongly to the wall during operation due to the continuous irradiation and also gradually spreads through adhering dirt.

Not only the wall of the radiation source itself, but also the wall of the elongated reactor vessel, in which the radiation source is mounted, will gradually contaminate, reducing the desired operation of the reactor as a whole.

The object of the invention is now to reduce the problems with regard to the vulnerability of the radiation source itself and the problems with regard to the pollution of the radiation source and of the reactor vessel, in particular the initial onset that occurs during the mounting of the radiation source, or to eliminate.

This object is fulfilled in an installation of the type mentioned in the preamble, in that the elongated light radiation source is pre-mounted in an elongated tube which is provided for this purpose near its ends with holders for fixing the radiation source and means for passing the connecting lines of the radiation source, which pipe is further provided near the ends with means for connecting the supply or the discharge to the pipe for supplying the liquid substance or the flowing material or the discharge thereof. By pre-assembling the elongated radiation source in an elongated tube, which can be done separately in a clean environment and under conditions, where no pollution of the radiation source or of the tube occurs, and the risk of breakage of the radiation source can also be minimized, a sub-composition is obtained which can be easily transported with little risk of breakage of the radiation source and also with little chance of contamination of the interior of this sub-composition. The subassembly can be mounted in a simple manner in the device, in which device a combination of a number of these subassemblies may optionally be present, wherein also during this mounting step there is little or no chance of contamination of the outer wall of the radiation source or the inner wall of the tube.

Preferably, the tube is made of a material which forms a good reflector for the radiation used, or a coating of a material which forms a good reflector for the radiation used is provided on the inner wall of the tube. Aluminum has in particular proved to be a suitable material for this purpose, in contrast to the stainless steel beam commonly used in the prior art, which forms a poor reflector for, inter alia, UV radiation.

Furthermore, in order to promote the reflective properties of the pipe wall and to reduce the chance of deposits of contaminants on the pipe wall, the inner wall of the pipe is smoothly finished. Aluminum has in particular proved to be a suitable material for this purpose, in contrast to the stainless steel beam which is frequently used in the prior art, which forms a poor reflector for UV radiation.

Each sub-composition forms a closed unit that the user cannot see during operation of the device. During operation of the device, however, contamination will occur both of the inner pipe wall and of the outer wall of the radiation source. In order to now provide the user with a simple indication of this degree of contamination, it is preferable that a window is provided in the tube, on the inside of which a thin layer is applied of a fluorescent material which under the influence of the radiation emitted by the radiation source itself radiation within the visible part of the spectrum will radiate and that the window is made of a material which transmits the latter radiation.

Preferably, the window is made of a material which is impermeable to the radiation emitted by the radiation source. This applies in particular to those applications in which the radiation source emits radiation which can be harmful to the environment, in particular to the user of the device. Suitably, the window can be made of perspex or glass, the composition of which is such that the radiation emitted by the radiation source is not transmitted.

Preferably, said fluorescent material on the inside of the window is provided with yttrium oxide activated with europium. In particular, this material will emit bright red light under the influence of UV radiation. The stronger the UV radiation, the stronger the intensity of the red light emitted. The user can thus easily determine, on the basis of the observed intensity, whether the contamination within a sub-composition has progressed so far that it is time to replace this sub-composition.

Furthermore, as the fluorescent material, cesium / gadolinium / terbium / magnesium borate can be used, which will emit bright green light under the influence of UV radiation, the intensity of which also depends on the intensity of the activating radiation.

Irrespective of the fluorescent substance, said material as carrier preferably contains silicone rubber.

The invention will be explained in more detail below with reference to the accompanying figures.

Figure 1 shows a section through a sub-assembly according to the invention.

Figure 2 shows a device according to the invention in which a number of sub-assemblies according to Figure 1 are included.

Figure 3 shows a section through one of the end plates of the device of figure 2.

Figure 1 shows a cross-section through a sub-composition according to the invention, which is in particular intended for disinfecting water using UV light. However, it will be apparent from the above that the invention is not limited thereto. The partial assembly shown in figure 1 comprises an elongated tube 10 within which lamp holders 12 and 14 are mounted near the top end and the bottom end, respectively. These lamp holders serve to fix and position the UV lamp 16. The lamp holders 12 and 14 each have openings, one of which is indicated by 18 in Figure 1 or is otherwise designed such that liquid (or the flowing medium (such as a gas), which flows through the tube from one end to the other, is hardly hindered by the lamp holders 12 and 14. At least one of the lamp holders 12 or 14 is provided with an electric cable 20, which is preferably led out through the wall of the tube 10 and ends, for example, in a contact plug 22 or the like.

It will be clear that the tube 16 is mounted in the housing holders 12 and 14 in such a way that the electrical contacts of the tube 16 as well as the connection of these contacts to the cable 20 cannot come into contact with the liquid flowing through the tube during operation. 10 flows. Some further details of the assembly are discussed below with reference to Figure 3.

The tube 10 is preferably manufactured from a material which is good UV-reflecting in itself or provided on the inner wall with a coating of a material that is in itself good UV-reflecting. Preferably, the inner wall of the tube is further smoothly finished, for example polished or in some other way limited, so that the highest possible reflection of the UV radiation is achieved and the chance of deposition of impurities on the wall is also reduced.

A window 24 is further arranged in the wall of the tube 10. On the inner wall of this window 24 there is a layer 26 of a fluorescent material, in particular a material which itself will emit light under the influence of UV radiation at a wavelength within the visible part of the spectrum. This light is transmitted through the window 24 to the outside and can therefore be perceived by the user of the device. As long as the inner wall of the tube 10 is clean and therefore no contamination has yet occurred, the material of the layer 26 will fluoresce strongly and therefore emit light of relatively strong intensity. However, as the fouling of the tube and the radiation source 16 increases and / or the efficiency of the radiation source 16 decreases, less UV radiation will be able to reach the layer 26 and therefore the intensity of the light emitted by the fluorescent layer will decrease. The user can thus easily determine on the basis of the perceived intensity of the radiation in the window 24 to what extent there is contamination within the sub-composition shown in figure 1.

Figure 2 shows very schematically the way in which some of the sub-assemblies of the type illustrated in Figure 1 can be combined into a reactor. In Figure 2, six sub-assemblies of the type, as illustrated in Figure 1, are sandwiched between two end flanges 30, 32. In Figure 2, only three of the six sub-assemblies, designated 10a, 10b and 10c, are visible. Each of these sub-assemblies has its own window 24a, 24b, 24c by means of which the user of the device can check the degree of contamination of the sub-composition in question. The flanges 30 and 32 are connected in a manner not further specified to the liquid supply or liquid discharge, in such a way that the liquid to be treated can flow through these flanges through the sub-assemblies 10a ... 10c and can be disinfected therewith with UV radiation. .

Figure 3 shows a possible manner of securing the sub-assemblies 10 in the end flanges 30 and 32. As an example, a section through part of the bottom flange 30 in which the tube 10a is mounted is shown. The flange 30 is provided with a number of openings 32 which have a stepped section in cross section. The lower part of the opening has a relatively small diameter, at least smaller than the inner diameter of the tube 10a, while the upper part of the opening 32 has a diameter corresponding to the outer diameter of the tube 10a. In particular, the end portions of the tube 10a are configured to fit snugly into the respective portion of the opening 32. To obtain a liquid-tight (or gas-tight) connection, use is made of a sealing ring 34 between the bottom end of the tube 10a and the flange 30. Instead of this ring, a sealing sealant, for example silicone sealant, can also be used in a known manner to obtain a liquid-tight (or gas-tight) connection. Also, for sealing the wall of the radiation source 16 with respect to the lamp holder 14, a kit can be used as indicated in the figure at 38.

The device shown in figure 2 can for instance be provided with tie rods between the flanges 30 and 32. After all the sub-assemblies 10a ... 10x have been put in place, the end flanges 30 and 32 are pulled together by means of these tie rods, so that the various sealing rings 34 or sealants used instead are slightly compressed thereby ensuring a good liquid tight seal.

The window 24 in each of the sub-assemblies consists of a light transmissive material generated by the fluorescent layer 26 on the inside of each window. Glass or perspex is preferably used for the window. Perspex in particular is a material which substantially transmits radiation in the visible part of the spectrum and which damps radiation to a greater or lesser extent outside the visible region, but does not transmit at all. Glass, in particular special types of glass, can also be used for the same purpose.

The window 24 can be easily mounted, for example, by gluing in a suitable opening in the pipe wall 10. In a preferred embodiment, the layer 26 may consist of yttrium oxide activated with europium. Under the influence of UV radiation, this combination itself emits bright red light at a wavelength of approximately 600 nm. Another very suitable material that can be incorporated in the layer 26 is constituted by cesium / gadolinium / terbium / magnesium borate which itself emits bright green light at a wavelength of about 542 nm upon excitation by UV radiation.

Claims (13)

Device for treating by means of light radiation of at least partially light-radiation-transmitting liquid substances or flowing materials, provided with one or more generally elongated light radiation sources which are located in an elongated reactor vessel where, during operation, the liquid substance to be treated or the flowing material is passed through, characterized in that the (or each) elongated light radiation source is pre-mounted in an elongated tube which is provided for this purpose near its ends with holders for fixing the radiation source and means for passing the connecting lines of the radiation source, which pipe is further provided near the ends with means for connecting the supply or the discharge to the pipe for supplying the liquid substance or the flowing material or the discharge thereof. Device according to claim 1, characterized in that the radiation source consists of a UV radiation source. Device according to claim 1 or 2, characterized in that the tube is made of a material which forms a good reflector for the radiation used. 4. Device as claimed in claim 1, characterized in that a lining of a material which forms a good reflector for the radiation used is arranged on the inner wall of the tube. Device according to claim 1, characterized in that the inner wall of the tube is smoothly finished. Device according to claim 1 or 2, characterized in that the tube is made of aluminum. 7. Device as claimed in any of the foregoing claims, characterized in that a tube is arranged in the tube, on the inside of which a thin layer is applied of a fluorescent material which itself radiates within the visible part under the influence of the radiation emitted by the radiation source. of the spectrum and that the window is made of a material that transmits the latter radiation. 8. Device as claimed in claim 7, characterized in that the window is made of a material which is impermeable to the radiation emitted by the radiation source. Device according to claim 7, characterized in that the window is made of perspex. Device according to claim 7, characterized in that the window is made of glass, the composition of which is such that the radiation emitted by the radiation source is not transmitted. Device according to any one of claims 7-10, characterized in that said fluorescent material contains yttrium oxide activated with europium. Device according to any one of claims 7-10, characterized in that said material contains cesium / gadolinium / terbium / magnesium borate. Device according to any one of claims 7-12, characterized in that said material uses silicone rubber as a support.