NL1014549C1 - Method for purifying water as well as a device suitable for carrying out such a method and device suitable for checking such a device. - Google Patents

Description

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Short designation: Method for purifying water as well as a device suitable for carrying out such a method and device suitable for checking such a device.

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The invention relates to a method for purifying water contaminated with at least one type of organic compound by irradiating the water with ultraviolet light, wherein ultraviolet light is used with a first wavelength range with at least a wavelength of approximately 185 nanometers and a second wavelength range of at least 200 to 400 nanometers.

The invention also relates to a device suitable for carrying out such a method and to an apparatus for checking such a device.

In such a method and device known from Dutch patent application 89.02.954, water is purified by adding cleaning agents to the water and then irradiating it with ultraviolet radiation.

Although with the wavelength ranges described in Dutch patent application 20 a reasonable purification of water is obtained, certain organic compounds appear not to be degraded, or not sufficiently. In addition, there is a risk that detergent residues remain in the purified water.

The object of the invention is to provide a method with which water can be purified better.

This object is achieved in the method of the invention in that while the second wavelength range includes wavelengths from 170 to 400 nanometers.

It has been found that if a specific wavelength of about 185 nanometers (for example 184.7 or 184.9 nm) is used with a relatively low intensity and in addition a wide wavelength range of 170 to 400 nanometers is used with a relatively high intensity, good purification is obtained. In particular, the extra wavelength range of 170 to 200 nanometers is responsible for improved purification. When purifying water in this way, the addition of cleaning agents is not necessary.

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Another object of the invention is to provide an apparatus with the aid of which, inter alia, a device according to the invention can be checked for correct functioning in a simple manner.

This object is achieved in the device according to the invention in that the device is provided with a conduit extending partly through the treatment chamber, which is connected to a control liquid-containing reservoir, a pump and a measuring device.

With the aid of the device, a control liquid is passed through the conduit located in the device past an ultraviolet lamp. Organic substances present in the control liquid are broken down by means of the radiation emitted by the ultraviolet lamp. The quantity of degraded organic compounds is determined with the aid of the measuring device. If the actual amount of decomposed organic compound corresponds to the expected amount of decomposed organic compounds, this indicates that the device is functioning as expected. However, if the quantity actually degraded is lower than the expected quantity, this is an indication that the device is not functioning properly, which can for instance be caused by wear or aging of the UV lamp or by deviations occurring in the previous process to which the water is subject. The UV lamp can now be replaced and the device can be checked again.

With the aid of the device according to the invention it is possible to continuously or periodically check the device without the device having to be stopped. Only if it is determined that the UV lamp needs to be replaced, the device must be temporarily stopped.

The invention will be further elucidated with reference to the drawings, in which: Fig. 1 shows a schematic view of an embodiment of a device according to the invention, Fig. 2 shows a cross-section of the device shown in Fig. 1, Fig. 3 shows a schematic representation of a device and an apparatus according to the invention.

Corresponding parts are provided with the same reference numerals in the figures.

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Fig. 1 shows a device 1 which is provided with a cylindrical treatment chamber 2 to which a water inlet 3 and a water outlet 4 are connected. The cylindrical treatment chamber 2 is closed near the water inlet 3 and the water outlet 4 by end walls 6 extending transversely to the center line 5 of the treatment chamber 2. Between the end walls 6 tubes 7, 8 extend, for example, made of high-quality quartz glass transmittance, particularly of wavelengths between 170-190 nm.

Ultraviolet lamps 9, 10 are located in the tubes 7, 8 and are supported by lamp holders located in the ends of the tubes 7, 8. For clarity, the tubes 7, 8 and the lamps 9, 10 located therein are also shown next to the treatment chamber 2.

The ultraviolet lamp 9 belongs to a second group of lamps with a second wave range of approximately 184.7 nanometers and 254 nanometers. In the exemplary embodiment shown here, the second group of UV lamps comprises only a single lamp. The center line 5 of the treatment chamber 2 extends through this lamp 9. The lamps 10, which extend parallel to the lamp 9, are located at a distance from the axis 5 and form a first group of lamps with a first wave range of 170 to 400 nanometers and more in particular 170 to 300 nanometers.

As visible in Fig. 2, in the exemplary embodiment shown here, the first group of lamps comprises 6 lamps. As clearly visible in Fig. 2, the tubular water inlet 3 extends transversely to the center line 5 of the treatment chamber 2, the axis of the water inlet 3 the center line 5 crosses. As a result, a stream of water introduced through the water inlet is directed substantially tangentially to the cylindrical treatment chamber 2. Due to the staggered water inlet 3, a swirling flow past the lamps 9, 10 is obtained with only a slight pressure drop of the water over the device 1, so that the water 30 located near the lamps is regularly refreshed.

The operation of device 1 according to the invention will now be explained in more detail.

The water to be purified, comprising one or more organic compounds, is supplied to the water inlet inlet 3, from which it flows into the treatment chamber 2 in the direction indicated by arrow P1. Since the water, as is clearly visible in Fig. 2, is introduced substantially tangentially to the treatment chamber 2, the water 2 present in the treatment chamber will undergo a rotating flow.

In the treatment chamber 2, ultraviolet light is emitted from the groups of ultraviolet lamps 9, 10. The lamp 9 of the second group emits ultraviolet light with specific wavelengths from 170 to 400 nanometers with a relatively high intensity, as a result of which this ultraviolet light will also reach the water located near the walls of the treatment chamber 2. The lamps 10 emit a wavelength of 184 and 254 nanometers with a relatively low intensity. However, because six lamps 10 are located in the treatment chamber 2, the lamps 10 irradiate all the water present in the treatment space 13 by ultraviolet light with wavelengths of the first wavelength range. In addition, the lamps 10 are irradiated by light from the lamp 9 with a wavelength of 254 nm. This results in a gain in the lamps 10 of the light emitted by these lamps 10 with a wavelength of about 185 nm (184.7 nm).

Due to the ultraviolet radiation of both the first wavelength range and the second wavelength range, the organic compounds in the water to be purified will oxidize, which oxidation process as activator has ultraviolet radiation of the first wavelength range which is emitted by the lamps 10. After the water has passed through the treatment 1 chamber 2 has flowed, it flows in the direction indicated by arrow P2 into the water outlet 4.

Fig. 3 shows an apparatus 1 according to the invention, which is coupled to an apparatus 20 according to the invention. The device 20 comprises a quartz tube comprising a pipe 21 extending parallel to a lamp 10 and which is connected to a flexible pipe 22 near end walls 6 of the treatment chamber 2. The flexible pipe 22 is connected to a pump 23, a shut-off valve 24, a of a base liquid, such as water-containing reservoir 25, a measuring device 26 and a control liquid-containing reservoir 28 connected to line 22 via a pump 27.

A diversion 29 is further connected to line 22. Two valves 30, 31 are arranged in the bypass 29. An ion exchanger 32 is located between the valves 35, 30, 31.

The electrical resistance of the liquid present in the line 22 can be measured with the aid of the measuring device 26.

The operation of the device 20 is as follows. A liquid located in reservoir 25, such as for instance water, is introduced into line 22 and pumped through the line 21 located in device 1 with the aid of the pumps 23. The liquid is then passed along the measuring device 26 where the electrical resistance of the liquid is read. If the base liquid is almost pure water, the electrical resistance is relatively high.

Subsequently, the valve 24 is closed while the valves 30, 31 are opened, through which the liquid is passed through the ion exchanger 32. After the liquid has been circulated a number of times, a constant value of the electrical resistance of the liquid is obtained. This value will be relatively high.

Thereafter, the valves 30, 31 are closed while the valve 24 is opened. Then, with the aid of the pump 27, a control liquid such as, for example, a 100% UV-oxidizable organic carbon source, for example alcohols, high-purity sucrose, etc., is supplied to line 22 in a predetermined dose. The liquid is again pumped through the line 21, whereby the organic compounds are broken down as a result of the UV radiation 20. Hereby ions enter the liquid, as a result of which the electrical resistance of the liquid decreases. Based on the amount of control liquid supplied to line 22, its composition and the UV light emitted by the amps, an expected degradation of organic compounds and an associated increase in ions in the liquid can be calculated. Based on the expected amount of ions, an expected electrical resistance can be calculated. If the expected electrical resistance deviates from the measured electrical resistance, this is an indication that the UV lamps no longer function optimally and the UV lamps must be checked and replaced if necessary.

If the expected electrical resistance does correspond to the measured electrical resistance, then the valve 24 is closed and the valves 30, 31 are opened so that the liquid present in the line 22 is passed through the ion exchanger 32, whereby the liquid regains its original electric resistance. .

After a predetermined time or at a time desired by a user, a control liquid can again be supplied from the reservoir 28 to the line 22 to check the operation of the device 1. It is of course also possible for the conduit 21 to extend over only a part of the treatment chamber 2.

It is also possible to check the composition of the liquid in the line 22 after treatment in treatment room 2 with a different type of measuring device.

It is possible to coat the inside of the treatment chamber 2 with a layer of titanium dioxide. This material has a catalytic effect on the oxidation of organic components.

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Claims (12)

A method for purifying water contaminated with at least one type of organic compound by irradiating the water with ultraviolet light 5, wherein ultraviolet light is used with a first wavelength range with at least a wavelength of approximately 185 nanometers and a second wavelength range of at least at least 200 to 400 nanometers, characterized in that the second wavelength range comprises wavelengths from 170 to 400 nanometers. A method according to claim 1, characterized in that the second wavelength range comprises wavelengths from 170 to 300 nanometers. A method according to claim 1 or 2, characterized in that the first wavelength range further comprises a wavelength of about 254 nanometers. 4. Device suitable for carrying out the method as claimed in any of the foregoing claims, which device comprises a treatment chamber, a water inlet and water outlet connected to the treatment chamber and first and second groups of ultraviolet lamps situated in the treatment chamber, wherein the first group ultraviolet lamps comprise a first 20 wavelength range with a wavelength of about 185 nanometers while the second group of ultraviolet lamps comprise a second wavelength range of at least 200 to 400 nanometers, characterized in that the second wavelength range of the second group of ultraviolet lamps further comprises wavelengths from 170 to 400 nanometers includes. The device according to claim 4, characterized in that the first wavelength range of the first group of lamps further comprises a wavelength of about 254 nanometers. 6. Device according to claim 4 or 5, characterized in that the treatment chamber comprises a cylindrical chamber extending along an axis and the lamps extend substantially parallel to the axis, the second group of lamps being located near the axis and the first group of lamps is located at a distance from the center line. 7. Device according to claim 4, 5 or 6, characterized in that the water inlet extends along an axis crossing the axis of the cylindrical treatment chamber. 8. Device suitable for checking one Device according to claim 8, characterized in that the conduit extends parallel to the ultraviolet lamp. 10. Apparatus according to claim 8 or 9, characterized in that the electrical resistance of the liquid can be measured with the aid of the measuring device. 10 U 5 4 9 device provided with a treatment chamber, a water inlet and water outlet connected to the treatment chamber and at least one ultraviolet lamp located in the treatment chamber, characterized in that the device is provided with a part extending through the treatment chamber extending conduit connected to a control fluid containing reservoir, a pump and a measuring device. 11. Apparatus according to any one of the preceding claims 8-10, characterized in that the conduit is provided with a bypass closable by means of the valves, in which an ion exchanger is located. Apparatus according to any one of the preceding claims 8-11, characterized in that the conduit is further connected to a reservoir containing a base liquid. I 0 U549