DE19832431A1 - Combined UV and ozone sterilization of a flowing liquid such as water - Google Patents

Abstract

Combined UV and ozone sterilization of a flowing liquid such as water. A device for sterilizing liquids has a flow tube (4) of quartz, or other UV transparent and ozone resistant material, in a housing (2) which contains a source of UV radiation which covers both the tissue destroying 254.7 nm and ozone generating 200 nm wavelengths. Air is supplied under slight pressure to the housing via an inlet (22), and the produced ozone is drawn into the liquid stream via a tube (25) fitted with a non-return valve (27). The device may be followed by an inverted U-shape trap (30) for removal of residual treatment gases from the liquid.

Description

The invention relates to a device for disinfecting a fluid by means of UV rays through a tube permeable to electromagnetic waves which conducts the fluid, and a housing surrounding the tube in which at least one UV lamp is arranged.

A device of the type mentioned is for example from DE-OS 196 17 467 known. When water is disinfected, the water flows through a quartz glass tube, and there is a UV-C lamp in the air space of the housing. The housing for the UV lamp is made of aluminum or with because of the high reflectance Coated aluminum paint.  

In order to achieve a high level of disinfection, the Utility model application 298 02 771.2 a device for disinfecting a Fluids proposed by means of UV rays, using appropriate sensors Fluctuations in the lamp power are recognized and appropriate measures for their Rectification can be carried out. It also makes it high Uniformity in the disinfection effect achieved.

The invention has for its object a further improvement of To achieve fluid quality. An even better cleaning of the fluid is said to be achieved become.

The problem is solved in a device of the type mentioned Genus according to the invention in that the electromagnetic waves of the UV-C lamps in the tissue-destroying range of 254.7 nm as well as in ozone generating range are below 200 nm. The preferred waveband is below 180 nm. Depending on the wavelength range of the radiation, a is used as a flow tube Quartz glass tube or a tube made of other suitable material is used. For the Radiators suitable for generating ozone are available on the market, as are the Quartz glass tubes for this purpose.

This is for the constant formation and supply of the generated ozone into the fluid Housing with an inlet connection for the Provide filtered air to the housing. The ozone generated in the housing  is added to the fluid. This is done via an inlet nozzle, which in Seen flow direction penetrates the first holder for the tube. They are too other supply points conceivable, but this arrangement offers the possibility of To allow ozone in the fluid to take effect in the radiation area of the emitters.

The device is preferably positioned so that the fluid in the tube flows vertically from bottom to top. In this case the Inlet fitting attached to the bottom of the housing, the side wall of which a metal pipe.

In order for the ozone to pass into the fluid, the air pressure in the housing set higher than the pressure of the fluid in the fluid pipe. This can be done at the inlet connection an air feed pump must be connected. The air pump and also a Air filters that are usually used can be of a known type. So with one possible pressure drop in the housing with a transfer of the fluid into the housing To avoid safety, the inlet connection is provided with a check valve.

Advantageously, an inlet pipe made of metal is on the inlet nozzle connected, the mouth of which is in the upper interior of the housing. Because the ozone lighter than air, it collects in this part of the interior and passes through the inlet pipe to the inlet nozzle.  

At the outlet sleeve of the fluid-carrying pipe are a gas separator and Gas neutralization device connected. This will cause excess gases or gas mixtures separated and neutralized.

The gas separator is extremely simple and inexpensive in its construction and can from a siphon-like pipe bend with one arranged at its apex Liquid shut-off valve be formed. The liquid shut-off valve leaves the Gas mixtures escape, but shuts off liquids.

An activated carbon canister can be used as the gas neutralization device. which neutralizes the gas mixture.

That is below a wave range of 200 nm with UV radiation of the air resulting ozone is consequently supplied to the fluid, which is already one UV radiation is subject to UV radiation. The UV radiation takes place in the Fluid a disinfection. The addition of ozone also causes an oxidation of organic compounds in the fluid, which are rendered harmless as a result, as well as a complementary killing of viruses and bacteria.

The invention is explained in more detail using an exemplary embodiment. It shows

Fig. 1 shows the sterilization device in longitudinal section and

Fig. 2 also shows the gas separator with activated carbon canister in section.

Fig. 1 shows a longitudinal section through the sterilizing device 1. The device 1 consists essentially of a housing 2 , in which the UV lamp 3 is arranged, and through which a tube 4 for the fluid is guided. The housing 2 is formed from a pipe section 5 and two end plates - an upper plate 6 and a lower plate 7 . The bottoms 6 and 7 are flange-shaped, inserted into the pipe section 5 and provided with a sealing ring 9 on their outer edges 8 . The attachment of the floors 6 and 7 on the pipe section 5 can be done in a suitable manner, for. B. via a screw connection.

A radiator 3 is shown . However, a plurality of radiators 3 are preferably arranged distributed over the circumference of the tube piece 5 in order to achieve the best possible effect of the radiators 3 in relation to the fluid flowing through the tube 4 . The electrical connection 10 for the radiator 3 is guided in an airtight manner through the lower base 7 via the screw connection 11 . The screw connection 11 consists of a socket 12 inserted into the base 7 with a threaded pocket 13 into which a sealing ring 14 is inserted, which is compressed by the screw 15 and thus seals the electrical connection 10 .

The tube 4 is edged at its ends 16 and 17 by screw connections 18 with seals and connected to the bases 6 and 7 via the sleeves 19 and 20 . The fluid flows through the tube 4 from bottom to top in the direction indicated by arrow 21 .

In the lower floor 7 , an inlet connection 22 is inserted, through which fresh air is conveyed into the housing interior 23 by a pump (not shown in more detail). It is filtered air so that the interior 23 is not contaminated and the lamp output is reduced.

The wave range of the emitters 3 is designed so that 23 ozone is generated from the air in the interior. This ozone collects in the upper part of the interior 23 , in which the mouth 24 of the inlet pipe 25 is located. The inlet pipe 25 leads to the inlet connector 26 in the holder 19th Via the inlet pipe 25 and the inlet connector 26 , the ozone generated is added to the fluid flowing through the pipe 4 and admixed. The admixture is brought about by the excess pressure prevailing in the tube 4 in the housing 2 . The latter is generated by the air pump. In order to prevent unwanted backflow through the inlet pipe 25 , the check valve 27 is used. To support the admixture, a perforated tube piece 29, which is closed at its end, is attached to the inlet connector 26 . This causes the ozone to be bubbled into the fluid.

In the upper floor 6 there is a glass optic 28 , through which an insight into the interior is possible. The effectiveness of the emitters 3 can be observed here.

It should be noted that the device may be equipped with additional facilities for Monitoring their effectiveness can be endorsed as in previous ones Utility models of the applicant have already been treated.  

In FIG. 2, in the section of gas separator 30 and the gas neutralizing device 31 is illustrated. The pipe bend 32 is screwed into the outlet sleeve 20 of the pipe 4 . The curvature of the pipe bend 32 points upwards. At its apex 33 is the opening 34 through which the gases accumulating in the pipe bend can escape. At the opening 34 connects the liquid shut-off valve 35 , which consists essentially of a housing 36 with inlet and outlet openings 37 and 39 and a closing ball 38 . The ball 38 closes the inlet opening 37 in its lowermost position. With increasing gas pressure in the pipe bend 32 , the ball 38 is raised and the gas can escape through the valve 35 . The gas passes through the opening 39 into the subsequent activated carbon canister 40 , which, as its name already says, is filled with activated carbon 41 . The gases are neutralized by the activated carbon 41 and subsequently reach the ambient air. In the event that not gases, but fluid is present at the opening 37 , the lighter ball 38 is raised by the fluid until it closes the opening 39 . The fluid can then not get into the activated carbon canister 40 .

The pipe bend 32 is provided at the drain end 43 with a screw connection, via which it can be connected to a drain pipe.

Claims (11)

1. Device for sterilizing a fluid by means of UV rays with a tube permeable to electromagnetic waves, through which the fluid is passed, and a housing surrounding the tube, in which at least one UV lamp is arranged, characterized in that the electromagnetic waves of the UV-C emitter ( 3 ) are both in the tissue-destroying range of 254.7 nm and in the ozone-generating range below 200 nm. 2. Device according to claim 1, characterized in that the wave range is below 180 nm.   3. Apparatus according to claim 1 or 2, characterized in that a quartz glass tube or a UV-resistant and transparent plastic tube is used as the tube ( 4 ). 4. Device according to one of claims 1 to 3, characterized in that the housing ( 2 ) with an outwardly through the housing wall ( 7 ) guided inlet connector ( 22 ) for the supply of filtered air in the housing ( 2 ) is provided and the first holder ( 19 ) of the tube ( 4 ), seen in the direction of flow ( 21 ) of the fluid, has an inlet connection ( 26 ) for the supply of the ozone generated into the fluid. 5. Device according to one of claims 1 to 4, characterized in that the inlet connection ( 22 ) in the lower bottom ( 7 ) of the housing ( 2 ) is attached. 6. Device according to one of claims 1 to 5, characterized in that the inlet connector ( 26 ) is provided with a check valve ( 27 ). 7. Device according to one of claims 1 to 6, characterized in that an inlet pipe ( 25 ) made of metal is connected to the inlet connector ( 26 ), the mouth ( 24 ) in the upper part of the interior ( 23 ) of the housing ( 2 ) . 8. Device according to one of claims 1 to 7, characterized in that the air pressure in the housing ( 2 ) is higher than the pressure of the fluid in the tube ( 4 ). 9. Device according to one of claims 1 to 8, characterized in that a gas separator ( 30 ) and a gas neutralization device ( 31 ) are connected to the outlet sleeve ( 20 ) of the fluid-carrying pipe ( 4 ). 10. Device according to one of claims 1 to 9, characterized in that the gas separator ( 30 ) consists of a pipe bend ( 32 ) with a liquid shut-off valve ( 35 ) arranged in its apex ( 33 ). 11. Device according to one of claims 1 to 10, characterized in that the gas neutralization device ( 31 ) is an activated carbon container ( 40 ).