NL1004856C2 - Purification and disinfection of water - Google Patents

Abstract

Purification and disinfection of water comprises treatment with a combination of an Ozone (O3)-containing gas, ultra-violet (UV) radiation and a photo-catalyst.

Description

-1-

Method and device for treating an aqueous liquid.

The invention (1) relates to an instrument for the treatment of an aqueous liquid with a large number of application areas such as the preparation of drinking water at water supply companies, camping sites and ships, etc. But also for cleaning swimming pool water (private / public ), as well as in industrial processes such as in technical & medical laboratories (semiconductor manufacturing, pharmaceutical industry, and all other processes that require very pure water). Water can also be treated from or for (reuse in substrate cultivation, home and zoo aquariums (sea and freshwater). The disinfectant effect of the instrument is based on the killing of (pathogenic) micro-organisms, algae and the oxidation of nutrients for algae by oxidation with ozone, OH radicals and destruction by short-wave light.The invention can thus greatly reduce the use of chlorides and other chemical disinfectants.The instrument is also suitable for treating industrial wastewater in which Oiganian and / or inorganic materials contain chemicals and (one or more) hydrocarbons, such as CN *, S ^ * and PCBs, which can be oxidized into harmless or less harmful substances that require no further attention or are easy to break down further.

20 Disinfection by UV light must be done for a long time to be effective. Because of the required power, high or medium pressure mercury lamps are often chosen, where the electrical efficiency in the desired spectral range is low. In addition, disinfection or oxidation by means of ozone in the water phase requires a high concentration of ozone and a long contact time. Moreover, the generation of ozone, from an etetic point of view, is an ineffective process.

The claimed invention (1) utilizes a number of physicochemical mechanisms combined in a single instrument to provide a particularly high efficiency in oxidation and disinfection relative to the consumed electrical power.

According to the invention (1), the photocatalysis, disinfection by means of UV light, ozone generation and degradation of ozone dissolved in the water phase are obtained by the same (low pressure) UV source (S)>). This results in a very high efficiency. The 1004856 -2-

In the invention (1), the photocatalysis, disinfection by means of UV light, ozone generation and degradation of ozone dissolved in the water phase are obtained by the same (low pressure) UV source (9). This results in a very high efficiency. The OH radicals generated in both the photocatalysis and the ozone decomposition 5 in the reaction chamber (5) have a higher oxidation potential than ozone. Moreover, a synergistic effect can be said, because the oxidative and disinfectant effect of the combination of UV light with ozone gas is much stronger than that of both components separately.

The UV quanta not adsorbed by the ozone or aqueous liquid can affect the (micro) organisms present in the water. The cell DNA can be damaged in such a way that the organism will no longer be able to reproduce or die, depending on the damage done. The remaining UV light hits a photocatalyst (4.11) (e.g. T1O2). So-called “electron-hole combinations” can be created by light, which in turn generate OH radicals at the catalyst surface.

Another feature of the invention over existing instruments in which a UV source is separated from a liquid by a quartz wall is the application of a dirt-resistant coating (6) on the outside of the quartz tube (7). This is to prevent tarnishing and thus transmission loss. This makes mechanical erasing systems unnecessary.

The invention (1) therefore relates to an instrument with method as mentioned in the preamble, which is characterized by an aqueous liquid to be treated in a combined treatment of an ozone-containing gas (10), ultraviolet radiation and a photocatalyst (4, 11). subjects. Also, the invention (1) is characterized by a very high electrical efficiency due to the effective use of a wide spectral region of a (eg low pressure) UV source (9) which is separated from the reaction chamber (5) by a quartz tube ( 7) with a dirt-repellent coating (6) on top. 1 100 48 56

The method according to the invention can be elucidated with reference to the annexed drawings, in which the invention (1), (Figure 1) as well as the device (Figure 2) -3- are schematically shown. The references will be used to clarify the device according to the invention.

The invention also relates to a device suitable for carrying out the method where it is defined above, which device comprises: a (packed) contact column (19) with a supply (16) for gas and / or gas containing liquid, a liquid discharge (18) and a gas discharge (17) with an ozone destructor (25) if desired. In the contact column, the ozone is transferred from the gas phase to the liquid phase as effectively as possible. Dissolving the ozone gas in the liquid phase is an essential part of the treatment according to the invention.

If the incoming liquid stream (13) contains cations such as iron and calcium, these can have a detrimental effect on the oxidation / disinfection effectiveness of the process. In particular, precipitate can form. An (electro) magnetic water treatment system (20) on the water inlet side (13) of the invention, as well as possibly in the cycle side (26) could (partly) counteract this precipitation. If there are floating parts in the incoming liquid flow (13) and micro-organisms clumped to them, this flow can be filtered (24) and / or treated ultrasonically (23), after which the disinfecting effect of the invention will increase because of the increased transmission and the increased treatment surface of the mechanisms. The 20 ozone generated in the invention (1) is added to the contact vessel (19) via line (10), pump (14) and possibly a venturi (15) in combination with a static mixer (15). After a certain residence time in this vessel (19), the water in the reaction chamber (5) of the invention (1) can be treated, discharged (12), or recycled. It will be clear to a person skilled in the art that the method and device according to the invention can undergo numerous modifications without departing from the spirit of the invention.

Centrally located in the invention (1) (Figure 1) are one or more UV sources (9) emitting a spectrum (s) such that wavelengths below 380 nm (e.g. 253.7 and 184.9 nm) are generated. Low pressure UV sources are ideal for this. Ozone generation takes place by rinsing this UV source (s) (9) with an oxygen-containing gas or by pure oxygen entering the invention (1) via (3). The gas leaves the invention (1) through the gas outlet (10). It is recommended that the 100 4 8 56 -4- filter the gas supply (3) from dust particles (21) to prevent contamination of the UV source (s) (9) and the surrounding quartz wall (7).

The chamber (8) in which the UV source (s) is located is separated from the reaction chamber (5) by a quartz wall (7) on which a water-repellent layer (6) such as a Teflon coating is applied on the water side or heat shrink tubing, or other material with similar performance and transmissive to UV light below 260 nm.

The liquid (ozone-containing) liquid to be treated from the contact vessel (19) is fed into the invention (1) via line (18) and, optionally, a descaling instrument, via feed (2) where it moves between the dirt-repellent layer (6) and the cylindrically shaped photocatalyst (4), passed through a photocatalytic acting auger (11). The auger can also function as a pump. The use of the screw has the advantage that the liquid to be treated is illuminated homogeneously, and a large catalyst surface is created. After treatment in the reaction chamber (5), the liquid leaves the device via outlet (12). After which it is used, discharged, or fed back into the contact vessel (19).

1004856 -5-

Reference numbers as used in Figures 1 and 2.

1. The invention.

2. Inlet for aqueous liquid with ozone gas dissolved therein.

5 3. Inlet for gas containing oxygen.

4. Photo catalyst.

5. “Reaction Chamber”: Aqueous liquid with ozone gas dissolved in it.

6 Dirt-resistant coating, permeable to UV light from 300 nm and lower.

7. Quartz glass transmissive to UV light of 300 nm and below.

10 8. Gas containing oxygen and ozone gas.

9. (For example, a low pressure) UV source, with minimum spectral lines around 184 nm and 2S4 nm.

10. Exhaust of gas enriched with ozone gas.

11. Auger with photocatalyst mounted thereon.

15 12. Outlet of the cleaned aqueous liquid.

13. Water input 14. Pump.

15. Venturi / water jet pump possible in combination with a static mixer.

16. Mixture of water enriched with ozone gas.

20 17. Flue pipe.

18. Contact vessel output.

19. Contact vessel.

20. (Electromagnetic) descaling instrument.

21. Air filter to remove dust particles.

25 22. “Short circuit” of the contact vessel.

23. Ultrasonic instrument.

24. Water filter (eg sand filter).

25. Ozone destructor.

26. (Electromagnetic) descaling instrument.

10048 56

Claims (5)

1. A method of treating aqueous liquid, characterized in that the aqueous liquid is subjected to a combined treatment of an ozone-containing gas, ultraviolet radiation and a photocatalyst. 2. Method as in 1 wherein the ozone-containing gas is formed by ultraviolet radiation or by an external ozone generator. 3. Method according to claim 1, characterized in that the ultraviolet radiation has a wavelength of 150-300 nm, in particular 184.9 or 172 nm, or 230-270 nm, for example 253.7 nm. Method according to claim 1, characterized in that the quartz wall on the liquid side is provided with a UV-translucent, dirt-repellent coating. 5 Method or system as indicated in the previous description. 100 46 5 6