NL2006265C2 - DEVICE AND METHOD FOR PHOTOCATALYTIC TREATMENT OF A FLUID. - Google Patents

Description

DEVICE AND METHOD FOR PHOTOCATALYTIC TREATMENT OF A FLUID

The invention relates to a device 5 for photocatalytically treating a fluid, such as water.

The treatment of a fluid with a photocatalyst is known per se. Due to the presence of a photocatalyst and light with a suitable wavelength, a chemical reaction occurs, or a reaction is accelerated.

A drawback of the known devices is that the light required has a limited penetration depth. In particular when UV light is used in water, the penetration depth of the light is low. In addition, a portion of the light can be absorbed by photocatalyst particles or other absorbent particles present in the fluid. As a result, the effectiveness of the treatment is low.

An object of the invention is to prevent or alleviate these problems and to provide an effective and efficient device for photocatalytic treatment of a fluid.

This object is achieved with the device according to the invention, the device comprising: - a container for holding a fluid, with at least one inlet and at least one outlet; - at least one field generator that creates an electric, magnetic or electromagnetic field 30 in use; - at least one light source placed in the holder and comprising a converter, which converter in use converts the field generated by the field generator into light; and 2 - a photocatalyst placed in the holder.

In particular, photocatalytic treatment of a fluid means the degradation of organic and inorganic substances and / or disinfection, such as reducing the number of viable microorganisms, including viruses, single-cell animals and plants, using a photocatalyst. Preferably the fluid is a liquid, such as water, but alternatively the fluid can be a gas.

The field generated by the field generator, for example a magnetic field or a radio wave, is in use converted to light by the transducer. This allows the light source to be provided wirelessly. The energy supply of the light source is wireless. This has the advantage that no wires or cables have to be used. This is particularly advantageous for large-scale applications. Multiple light sources can be movably provided in a fluid in the holder, without their freedom of movement being restricted by a wire or cable. In addition, wires are prevented from becoming entangled.

A further advantage is that a plurality of light sources can be arranged in the holder as a fluidized bed.

The distance between the at least one light source and a volume element of the fluid to be treated is hereby as small as possible. This is particularly advantageous when the photocatalyst is designed as fine particles, since they absorb light. Even if other absorbent particles are present, the device 30 according to the invention offers a solution. Because a plurality of light sources are provided in the fluid, it is achieved that light penetrates into the entire volume of the fluid. This is particularly advantageous when light with a low penetration depth is used, such as UV light.

Because the light sources in the device according to the invention are in use distributed over the volume of the fluid, a substantially uniform photon flux distribution within the holder is obtained. A lower light intensity can hereby suffice with respect to light sources arranged at a fixed position in the holder.

Instead of increasing the intensity of the light produced to compensate for the absorbing capacity of the photocatalyst or other absorbent particles present, multiple light sources are provided that are distributed over the fluid. This is therefore energy efficient.

A further advantage is that the device according to the invention can easily be scaled up. In a larger device, more light sources are simply added. These do not have to be installed or cabled separately, since they use the field already installed for their energy supply.

The light source is preferably located in a transparent, watertight housing. As a result, the light source is fully or partially shielded from the fluid 25 and possible damage, for example due to a short circuit, is prevented or prevented.

A further advantage of the device is that it is possible to dispense with complex installations that direct photons to the photocatalyst, such as parabolic light reflectors.

The container can for instance also be a pipe system, such as a drain system.

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The photocatalyst can be designed in various ways. For example, the photocatalyst particles are immobilized by fixation on activated carbon, mezoporane materials, fibers or membranes.

In a preferred embodiment according to the invention, the photocatalyst is free in the holder, such that in use the photocatalyst is displaceable by a fluid present in the holder.

For example, the photocatalyst consists of fine particles, for example nanoparticles, such as Degusta P-25 T102 particles in suspension form.

By designing the photocatalyst as fluid-displaceable particles, it is ensured that the photocatalyst can move through the volume of the fluid, whereby effective treatment thereof is obtained. An additional advantage is that a relatively large reaction surface is obtained in this way.

Optionally, means are provided for setting fluid into motion in the container, with which the photocatalyst particles can be moved through the fluid in use.

For example, the photocatalyst is designed as particles of such a size that separation of the particles from the fluid is simple.

In a preferred embodiment of the present invention, the photocatalyst is a heterogeneous photocatalyst.

Providing a heterogeneous photocatalyst 30 means that the catalyst preferably does not dissolve in the fluid to be treated. This has the advantage that the catalyst can be easily separated from the fluid. In addition, heterogeneous photocatalysis can be applied at room temperature and normal pressure. Moreover, the secondary pollution is absent or low. Furthermore, heterogeneous photocatalysis can be used with low operating costs.

Preferably, the photocatalyst is a semiconductor photocatalyst, such as T102, ZnO, Fe2O3, CDS, GaP, ZnS. Most preferably, the photocatalyst is TiO 2. An advantage of T102 is that this catalyst remains stable after repeated catalytic cycles. In addition, TiO 2 is a thermally and chemically stable catalyst, which is furthermore resistant to chemical degradation. Moreover, T1O2 has strong mechanical properties. In particular, semiconductor photocatalysts are used in advanced oxidation processes (Advanced Oxidation Processes, AOPs).

Advanced oxidation processes are based on the principle of creating free radicals in situ, such as H 2 O 2, OH 2, O 2, O 3 for oxidizing organic and inorganic substances, for example hormones, medicines and disinfection by-products, such as by-products of chlorination.

For example, aromatic compounds are hydroxylated by a reactive OH.-radical, leading to successive oxidation / addition reactions and ultimately to the opening of the aromatic ring. This results in intermediates, especially aldehydes and carboxylic acids, which are further carboxylated to form carbon dioxide and water. The free radicals can also prevent microorganisms such as pathogens, kill them or at least prevent their multiplication.

In an advanced oxidation process with a photocatalyst, an electron-hole pair (electron-hole pair, eh-pair) is formed when photons with an energy greater than or equal to the forbidden zone (bandgap) 6 of the catalyst, be absorbed by the catalyst. Subsequently, a series of redox reactions occurs, creating free radicals.

Surprisingly, the invention is particularly advantageous when it is used in an advanced oxidation process.

For example, the light source is integrated with the photocatalyst. For example, a powdered or otherwise finely divided photocatalyst is mounted on a transparent envelope that surrounds the light source. This ensures that the light source is sufficiently close to the photocatalyst. Moreover, the photocatalyst can be easily separated from the fluid by removing the light source from the fluid.

In a presently preferred embodiment of a light source integrated with the photocatalyst, the integration is carried out with a kind of pump element. Such a pump comprises a housing provided with a reactor chamber, an inlet for entering and leaving fluid in and out of the reactor chamber, and a piezo element provided drivably on at least one side of the reactor chamber. Such a pump element can, if desired, also be used as a hydrophonic pump. The pump element provided with light source and photocatalyst can for instance be supplied with energy from an applied electromagnetic field in order to realize the inflow and outflow to and from the reactor chamber. A light source and / or a catalyst can be provided in the inlet and / or reactor chamber. In this way a compact embodiment can be realized which can be active even in a stationary fluid.

In a preferred embodiment according to the invention, the converter comprises an electrical conductor for generating an induction voltage in a magnetic field.

The conductor generates an induction voltage when a magnetic field is applied with the field generator. The induction voltage is applied to light the light source. In this way a wireless energy transfer is achieved.

In a further embodiment the device comprises a capacitor which is operatively connected to the conductor and light source, so that a tuned circuit is formed.

The conductor for generating induction voltage is operatively connected to a capacitor and optionally to a resistor. By choosing a correct value of the capacitor, and optionally the resistor, the resonance frequency of the circuit can be chosen. A resonant-inductive coupling of the light source with the generated magnetic field is hereby possible.

This has the advantage that optimum energy transfer takes place.

For example, in the embodiments described above, an induction voltage is generated by moving the electrical conductor in a magnetic field.

Preferably the electrical conductor is a coil. As a result, an induction voltage can be generated in a time-varying magnetic field.

Preferably, the field generator in use generates a time-varying magnetic field. As a result, the induction voltage generated is not dependent on movement of the electrical conductor. The time-varying magnetic field is preferably a magnetic field that oscillates with a fixed frequency.

In a further preferred embodiment according to the invention, the electrical conductor is manufactured by means of micro-machining. This makes the light source compact.

For example, the conductor is etched. Preferably both the electrical conductor and electrical components connected thereto, such as capacitors and / or resistors and the light source itself, are manufactured by means of micro-machining, such as etching, for example on a printed circuit board. An integrated circuit is hereby obtained which can serve as a light source in the device 10 according to the invention. This means that it can be made relatively small.

The light source in the device according to the invention is preferably an ultraviolet (UV) light source. For example, the light source is a UV LED. In particular, a UV light source is provided in combination with a T102 photocatalyst. T102 has a forbidden zone corresponding to wavelengths of light in the ultraviolet region of the spectrum, typically wavelengths of 300-390 nanometers. A problem that occurs with the use of ultraviolet light in the known devices is that UV has a very low penetration depth in water. By applying a UV light source in the device according to the invention, this problem is counteracted.

In a preferred embodiment of the device according to the invention, the light sources have a mass volume displacement of 0.1-1.2 g / cm3, preferably 0.4-1.2 or 0.5-1.1 or 0.6 -1.0 or 0.8-1.0 or 0.9-1.0 g / cm3. These mass / volume displacement values make the at least one light source suitable for being packed as a fluidized bed in the volume of the container when using a fluid that is gaseous or an aqueous liquid at room temperature.

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In a preferred embodiment according to the invention, the field generator is located in the holder.

By providing the generator in a holder, the field 5 generated in use by the field generator is not or hardly disrupted by the holder. For example, in the case of a magnetic field generator located within the holder, the magnetic field is hardly affected by the dielectric properties or the magnetic susceptibility of the holder. Moreover, the field generator is in this way as close as possible to the fluid to be treated, which is energy efficient. There is a better coupling when the field generator is inside the holder.

The invention further relates to a method for photocatalytically treating a fluid, comprising: - guiding a fluid into a container; - applying an electric, magnetic or electromagnetic field; - placing in the holder at least one light source which comprises a converter which in use converts the applied field to light; - placing a photocatalyst in the holder; - guiding the fluid out of the container.

This method has the same advantages and effects as described above for the device according to the invention. The method is preferably used in combination with the device as described above.

In an embodiment according to the present invention, the method is combined with the use of ozone, H2O2 and / or ultrasonic sound.

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The addition of ozone or H2O2 and the application of ultrasonic sound already have a disinfecting or oxidizing effect on the fluid. In combination with the described method for the photocatalytic treatment of a fluid, various methods are advantageously combined. It is also possible to combine other treatment methods with the present invention.

The invention further relates to a light source for use in the device as described above, comprising a converter which in use converts the field generated by the field generator into light and a photocatalyst.

In the light source according to the invention, the photocatalyst is integrated with the wireless light source.

For example, a powdered photocatalyst is mounted on a transparent shell that encloses a light source, such as an LED. This ensures that the light source is sufficiently close to the photocatalyst.

Moreover, the photocatalyst can be easily separated from the fluid by removing the light source from the fluid. The light source can also be integrated with the photocatalyst in a type of pump element, as described above.

Further advantages, features and details of the invention are elucidated on the basis of preferred embodiments thereof, wherein reference is made to the accompanying drawings.

Figure 1 shows a schematic representation of a device according to the invention;

Figure 2 shows the device of Figure 1 in use; 11

Figure 3 shows a light source for use in the device according to the invention;

Figure 4 shows an alternative embodiment of a light source for use in the device according to the invention;

Figure 5 shows the circuit diagram of the light source of Figure 4.

Device 2 (Figure 1) has an outlet 4 and an inlet 6 for introducing water to be treated through inlet 6, and outputting treated water via outlet 4. Device 2 comprises a holder 8 in which light sources 10 are located. In addition, container 8 contains photocatalyst 12 in the form of fine particles, in this case nanoparticles. Alternatively, photocatalyst 12 is designed as larger particles, for example the size of a few millimeters or centimeters, or immobilized. The UV light sources 10 and photocatalyst 12 are kept within holder 8 by filters 14.

In use, water flows according to arrow 18 (Figure 20 2) via inlet 6 through holder 8 towards outlet 4, where it leaves holder 8 according to arrow 20. Through this flow, light sources 10 and photocatalyst particles 12 move through holder 8. The device 2 is equipped with an additional housing 16 within which a magnetic field is generated by means of coils (not shown). The housing 40 is made of metal, so that a Faraday cage is created.

Light source 10 comprises an LED 22 (Figure 3) which is electrically connected to coil 24 with ferrite core 26. The whole is encased in transparent cover 28.

Alternatively, light source 10 is provided with two LEDs 30, 32 (Figures 4, 5).

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In an embodiment of a light source according to the invention, the envelope 28 of figure 3 is covered with a photocatalyst in powder form.

For water treatment, this is guided via inlet 6 into holder 8 of device 2. The water flows through outlet 4 from the container. This can be a continuous process, or batchwise. In the case this is batchwise, means are optionally provided for moving the liquid in the container 8 or container. The field generator (not shown) is switched on, whereby a magnetic field is applied over holder 8. By induction in coil 24, a voltage is created, as a result of which LED 22 starts emitting light. Light sources 10 with LEDs 22 emit UV light. The emitted photons have an energy that is greater than or equal to the forbidden zone of the photocatalyst material 12, in this case TiCt, titanium dioxide. This creates an electron-hole pair that enables a series of redox reactions that create free radicals. The free radicals break down inorganic and organic compounds into CO2 and water. In addition, microorganisms such as pathogens, algae and bacteria are killed.

The present invention is by no means limited to the above described preferred embodiments thereof. The rights sought are defined by the following claims, within the scope of which many modifications are conceivable. For example, it is possible to treat fluids other than water with the device or method according to the invention, such as a gas, a sugar solution, beer, blood or urine.

Claims (16)

A device for photocatalytically treating a fluid comprising: 5. a container for holding a fluid, with at least one inlet and at least one outlet; - at least one field generator that creates an electric, magnetic or electromagnetic field in use; 10. at least one light source disposed in the holder and comprising a converter, which converter in use converts the field generated by the field generator into light; and - a photocatalyst placed in the holder. Device as claimed in claim 1, wherein the photocatalyst is freely located in the holder, such that in use the photocatalyst is displaceable by a fluid present in the holder. The device of claim 1 or 2, wherein the photocatalyst is a heterogeneous photocatalyst. The device of claim 3, wherein the photocatalyst is a semiconductor photocatalyst. 25 The device of claim 4, wherein the photocatalyst is TiO 2. 6. Device according to at least one of claims 1-5, wherein the light source and the photocatalyst are integrated. Device according to at least one of claims 1-6, wherein the converter comprises an electrical conductor for generating an induction voltage in a magnetic field. 5 Device as claimed in claim 7, comprising a capacitor which is operatively connected to the conductor and light source so that a tuned circuit is formed. Device as claimed in claim 7 or 8, wherein the electrical conductor is a coil. 10. Device as claimed in at least one of the claims 7-9, wherein the electrical conductor is manufactured by means of micro-machining. The device according to at least one of claims Ι-ΙΟ, wherein the light source is a UV light source. Device according to at least one of claims 1 to 11, wherein the light source has a mass / volume displacement of 0.1-1.2 g / cm 3, preferably 0.4-1.2 or 0.5-1 or 0.6-1 or 0.7-1 or 0.8-1 or 0.9-1 g / cm 3. Device according to at least one of claims 1 to 12, wherein the field generator is located in the holder. 14. Light source for use in a device according to one or more of the claims 1-13, comprising a converter which in use converts the field generated by the field generator into light, and a photocatalyst. A method for photocatalytically treating a fluid, comprising: - guiding a fluid into a container; - applying an electric, magnetic or electromagnetic field; - placing in the holder at least one light source which comprises a converter which in use converts the applied field to light; - placing a photocatalyst in the holder; 10. guiding the fluid out of the container. The method of claim 15, comprising applying ozone, H 2 O 2 and / or ultrasonic sound.