NL1035089C2 - Disinfection device for e.g. water, has UV or electrode disinfection units packed inside volume of vessel for receiving contaminated fluid - Google Patents

Abstract

The disinfection units are packed inside the volume of the vessel which receives contaminated fluid and from which the disinfected fluid exits. A fluid disinfection device comprises a vessel for a fluid with at least one inlet for contaminated fluid and at least one outlet for disinfected fluid, as well as disinfection units located inside the vessel and each comprising a disinfection means chosen from UV light sources (1), direct current (DC) electrodes or alternating current (AC) electrodes, or a combination thereof. These units are packed inside the vessel volume. Independent claims are also included for the following: (1) Disinfection unit comprising an electric conductor (2) for generating inductance in an alternating electrical and/or magnetic field, a disinfection means connected to this conductor and chosen from a UV light source, multiple electrolytic electrodes and multiple AC electrodes, optional electrical circuit components electrically connected to the conductor and disinfection means and an optional casing for the conductor, disinfection means and optional electrical circuit components; (2) Method for disinfecting a fluid by introducing it via the inlet in the above device, generating an alternating electromagnetic field and allowing the disinfected fluid to leave via the outlet; and (3) Apparatus comprising a flat body with photovoltaic cells on one side and disinfection units on the other side, which are electrically connected to the cells and chosen from UV light sources, electrolytic capacitors or AC electrodes, or a combination thereof, the mass/volume displacement of the device being less than that of water.

Description

Device and method for disinfecting a fluid

According to a first aspect, the present invention relates to a device for treating a fluid, for example water, for the disinfection thereof.

According to a second aspect, the invention relates to a disinfection unit which is used in and forms an important part of a number of embodiments of the device according to the invention.

According to a third aspect, the invention relates to a method for treating a fluid, for example water, for the disinfection thereof.

Disinfection is an important process in the production of drinking water.

Since the production of drinking water is a bulk process, disinfection requires a relatively large amount of chemicals or energy. For this reason it is of great social and economic importance to develop water treatment methods that make it possible to disinfect water in a sustainable way. Furthermore, it is of social importance to develop robust decentralized water treatment methods that can be used in remote areas or in emergency situations to make water suitable for human consumption. There are also situations where it is important to disinfect a biologically contaminated fluid (for example, a waste water stream or a gas stream from a venting duct of a hospital or a microbiological laboratory) before it is released to the environment.

Water disinfection using ultra violet light is a known method per se (see for example US6303086 BI). A persistent problem with this method is the fact that the ultraviolet light has a very low penetration depth into the water, in particular if absorbent particles are present therein. It is therefore advantageous to keep the distance between the UV source and a volume of water element to be treated as small as possible.

Another known principle for disinfection of water uses an electrode pair with a direct voltage over it. Due to the direct voltage across the electrodes, electrolysis occurs in the water to be treated. The radicals released at the anode have a disinfecting effect. This technique is described, for example, by Bergman et al. (Chemical Engineering Journal Volume 85, Issues 2-3.28 January 2002, Pages 111-117) Due to the high degree of reactivity of the radical species, it is also advantageous in this application to distance between the radically forming anode and a volume of water element to be treated should be as small as possible.

Yet another principle with which a disinfecting effect can be achieved is based on the use of an alternating electric field with a frequency of the order of magnitude 100 kHz. From the literature (see, for example, Shuehiro et al. Sensors and actuators B96 (2003) 144-151), it is known that the cell membrane of micro-organ becomes permeable if the micro-organism is exposed to such an alternating voltage and that the organism is exposed to such an alternating voltage. correct combination of alternating voltage frequency, alternating voltage amplitude and exposure time.

In this application, too, it is advantageous to keep the distance between the electrodes and a volume of water element to be treated as small as possible.

The present invention makes it possible to disinfect a fluid, for example water, with the aid of one or more of the above principles with a solution that can be used on a large or small scale. Further advantages of a number of embodiments of the invention are a robust, low-maintenance design.

In the invention, UV light and / or other electromagnetic disinfectants, such as direct voltage electrodes or alternating voltage electrodes, can be introduced deep into the fluid, for example water. This is done by using UV-light sources, and / or direct-voltage electrodes and / or alternating-voltage electrodes with small-scale dimensions as disinfectants. Because of these small-scale dimensions of the disinfectants, it is possible to obtain a packing, for example a packed bed (including a fluidized bed) or a packed strand with disinfectants. In such a gasket, the distance of the disinfectants to the volume of fluid elements to be treated can be kept small.

According to a first aspect, therefore, the invention relates to a device for disinfecting a fluid, comprising a container for holding a fluid, with at least one inlet for introducing the fluid to be disinfected and at least one outlet for discharging the fluid into the container. removing disinfected fluid and further placed in the container a number of disinfection units comprising an electrically driven disinfectant selected from UV light sources, direct current electrodes or alternating current electrodes or a combination thereof. The device is characterized in that the disinfection units are packed in the volume of the container. The volume of the container is herein in particular preferably occupied by disinfection units.

The fluid being disinfected is, for example, a liquid, for example water, at room temperature, but may alternatively be a gas. The invention is suitable for disinfection of surface water, spring water or ground water, for example to make this (more) suitable as drinking water for human or veterinary use. The invention can also be used to disinfect process water from the beer industry, waste water or a gas stream from a venting system of hospitals, waste water or a gas stream from a venting system from the bio-industry, or sewage water to reduce the biological burden on the environment when discharging it. Reduce.

The device and the material of the container can easily be determined by the skilled person. The only important thing is that the container is suitable for holding the fluid and the disinfection units.

The container comprises at least one inlet and at least one outlet for respectively introducing the fluid to be disinfected into the container and for removing disinfected fluid from the container. At least one within the scope of this specification, whenever used, includes one or more, such as a multiple, i.e., two or more. It should be understood that in certain embodiments one or more inlets can also serve as outlet and vice versa. This is possible, for example, when using a batch version. In other embodiments, however, it is preferred that inlets and outlets are separate (e.g., in a continuous operation).

Within the scope of the present invention, disinfection means a reduction in the number of viable microorganisms, including viruses, single-cell animals and plants. The reduction is preferably to a level that is accepted in the EU for drinking water intended for veterinary and preferably human use. This also includes ensuring this microbial quality of the treated fluid. In other embodiments, the reduction is to a level that allows release to the environment.

The number of disinfection units comprises a disinfectant selected from UV light sources, direct voltage electrodes or alternating voltage electrodes or a combination thereof.

4 · * 4

Thanks to recent technological developments in the field of semiconductor technology, LEDs are commercially available that produce light in the UV region below 300 nm. Application of these UV LEDs in combination with the technology according to the present invention offers promising possibilities for disinfection. UV-LED technology has the great advantage over traditional UV lamps that the light output is much higher or, in other words, the amount of UV light emitted per Watt electrical power is very high. In addition, the lifespan of UV LEDs is much longer than that of conventional UV lamps and UV LEDs are not shock sensitive. Due to their small dimensions and impact resistance, UV LEDs are also suitable for being packed in, for example, a packed bed, including a fluidized bed. A steng of UV LEDs can also be manufactured, which can be packed in the volume of the container. When packing UV-LEDs in the volume of the reactor, for example in a packed bed or by using a strand of UV-LEDs, a large light-emitting surface is created. As a result, the power emitted by the UV LEDs is optimally utilized since the penetration depth of UV light into water is limited. Furthermore, UV-LED technology has the great advantage over traditional UV lamps that the light output is much higher or, in other words, that the amount of UV light emitted per Watt electrical power is very high. In addition, the lifespan of UV LEDs is much longer than that of conventional UV lamps and UV LEDs are not shock sensitive.

Instead of a UV radiation source as a disinfectant, an alternating electric field can also be used for disinfection with the technology according to the present invention. Use is made of a pair of alternating current electrodes. An alternating voltage of 10 Hz to 100 GHz such as 70-150 kHz, for example of the order of 100 kHz, is applied over these electrodes.

Within the scope of the present invention, frequencies within this range also include radio waves with a carrier wave modulated by amplitude modulation and / or frequency modulation and / or single sideband modulation. It is known that the cell membrane of microorganisms becomes permeable if the microorganism is exposed to such an alternating voltage and that the organism dies with a correct combination of alternating voltage frequency, alternating voltage amplitude and duration of exposure.

Instead of UV radiation or an alternating voltage, a direct voltage can also be used for disinfection with the present invention. In this latter application, a direct voltage is applied over two electrodes. Due to the direct voltage across the electrodes, electrolysis will occur in the water to be treated and the radicals and / or other reactive species (including, for example, hydroxide and chlorine species) which cause the anode will cause disinfection.

According to a preferred embodiment of the disinfection device, each disinfection unit comprises an electrical conductor suitable for generating an induction voltage in an alternating electric and / or an alternating magnetic field (including a radio wave) and a disinfectant electrically connected to the electric conductor. The disinfectant is selected from a UV light source, a number of direct voltage electrodes, a number of alternating voltage electrodes. Further, the disinfection device optionally comprises additional electrical switching components electrically connected to the electrical conductor and the disinfectant and an optional housing for the electrical conductor, the disinfectant and the further optional electrical switching components. The device further comprises means for generating an alternating electromagnetic field suitable for generating an induction voltage in the electrical conductor of the disinfection units. The electrical conductor is preferably a coil-like, electrically conductive wire and is more preferably an electrically conductive wire wound around a metal core, such as a ferrite core.

It is known that by means of induction electrical energy can be transferred from an electrical circuit A to another electrical circuit B while these electrical circuits are galvanically isolated. A typical application from current practice is, for example, a type of an electric toothbrush in which a coil is arranged in the watertight housing of the toothbrush. A second coil is provided in a likewise watertight housing and the toothbrush is charged by energy transfer from the charger coil to the receiving coil.

In the present invention, energy is transferred by means of an alternating electric field and / or an alternating magnetic field from a primary circuit to preferably a large number of secondary circuits located in a fluid 30. The primary circuit and the secondary circuits are galvanically isolated. In a preferred embodiment, the secondary circuits form a packed bed, including a fluidized bed of, for example, spherically shaped particles (e.g., marbles). A secondary circuit is present in every marble. Each secondary circuit can be made up of an electrical conductor, preferably designed as a 6 coil, whether or not equipped with a metal core, for example a ferrite core, which is connected to an electromagnetic disinfectant (for example a single UV LED or two anti-parallel connected UV LEDs). This makes it possible to control a large collection of disinfectants, for example UV LEDs, from the primary circuit.

By applying a number of secondary circuits equipped with UV LEDs in the form of a fluidized bed, it is possible to disinfect water in a robust, durable and highly effective way. An important additional advantage that the use of a fluidized bed entails is that the particles that make up the fluidized bed collide. Thanks to these collisions, a small amount of erosion occurs, so that the light-transmitting surface of the LEDs is not contaminated. Contamination of the UV radiation transmitting surface is a major disadvantage of the traditional UV lamps.

It will be clear to the skilled person that a packed bed, including a fluidized bed, is one of the many embodiments of the technology according to the present invention. Some of the alternative embodiments are stirred systems, pulsed systems and systems with a packed bed that is swirled from time to time.

Instead of UV radiation as a disinfecting element, with the technology according to the present invention an alternating electric field can also be applied for disinfection. For this purpose two electrodes are connected to a secondary circuit which are in contact with the liquid. This is possible, for example, by connecting the coil of the secondary circuit to two electrodes. By now applying an alternating voltage in the primary circuit with a frequency of 10 Hz-100 GHz such as 70-150 kHz, for example of the order of 100 kHz applied. An alternating voltage of a similar frequency arises between the two electrodes in each secondary circuit. It is known that the cell membrane of microorganisms becomes permeable if the microorganism is exposed to such an alternating voltage and that the organism dies with a correct combination of alternating voltage frequency, alternating voltage amplitude and duration of exposure. Within the scope of the present invention, frequencies within said range also include radio waves with a carrier wave modulated by amplitude modulation and / or frequency modulation and / or single sideband modulation.

Instead of UV radiation or an alternating voltage with a frequency of 7 orders of magnitude 100 KHz, a direct voltage can also be used for disinfection with the present invention. In this latter application, the coil of a secondary circuit is connected in series with a diode or a rectifier bridge and preferably a capacitor. A direct voltage is generated in this way. The capacitor is connected to two DC electrodes. Due to the direct voltage across the electrodes, electrolysis starts to occur in the water to be treated and the radicals and / or other reactive particles released at the anode cause disinfection.

It will be clear to those skilled in the art that the secondary circuit can be implemented by using miniature components in the form of a fluidizable bed of particle 10. It will also be apparent to those skilled in the art that application of the present technology to effect a fluidized bed on particle-scale electrolysis places demands on the shape of the particles and the positioning of the electrodes. These requirements for shape and positioning of the electrodes are imposed on the one hand by flow-related boundary conditions to keep the bed of particle fluidized and, on the other hand, by the precondition that, in the event of collision of the particles, no short-circuit by discharge of the capacitors in the colliding particles may occur, as this leads to energy loss. Configurations that meet these requirements are, for example, porous spherical particles with an electrode on the inside and an electrode on the outside. This configuration reduces the chance that the electrodes of two or more colliding particles make contact with each other in such a way that discharge of the capacitors of the individual particles occurs. Particles specially designed to use the new form of fluid bed electrolysis described herein are emphatically part of the present invention. Such particles also include, for example, hollow cylindrical particles in which the electrodes, for example direct-voltage electrodes or alternating-voltage electrodes, are placed within the circumference of the jacket. As a result, mutual contact between electrodes of different disinfection units is largely prevented. When a cylindrical shape is used, the cylinder casing can advantageously be used to wind a coil. The cylinder casing can then be formed of a metal, such as phenrite. And the electrodes may be placed electrically insulated from the jacket within the jacket circumference. The sheath can have a diameter of 10 µm to 1 cm, such as from 100 µm to 0.5 cm, or 500 µm to 0.1 cm. The length of the cylinder casing can be within the same order of magnitude, it being preferred that the length is greater than the I * 8 diameter. For example, the length is 2-5, such as 3-4 times the diameter.

Also, in a packed bed, including a fluidized bed, a number of inert particles (dummy particles) without electrodes can be used in an amount of 10-70%, such as 30-50%, preferably 30-40% on the total of the 5 particles in the bed. As a result, the mutual contact between the disinfection units with electrodes is reduced, as a result of which contact between electrodes is limited. In the combined use of disinfection units with electrodes and disinfection units with UV LEDs, the LED-containing particles will have a similar effect as dummy particles.

With regard to the process conditions in which the primary circuit is operated, it is noted that the frequency and amplitude of an alternating voltage that is applied to a primary coil depends on the application and can vary between 1 Hz and 100 GHz, such as for example 20-1000, 50- 800, 100-500, 200-400 Hz, 20-1000, 50-800, 100-500, 200-400 kHz, 1-80, 10-70, 20-60, 30-50 GHz.

According to a preferred embodiment of the device, the disinfection units have a mass / volume displacement of 0.1-3, preferably 0.1-2.2 g / cm 3, such as 0.4-1.2 or 0.5-1, 1 or 0.6-1.0 or 0.7-1.0, or 0.8-1.0, or 0.9-1.0 g / cm 3. These mass / volume displacement values make the disinfection units suitable to be packed as fluidized bed in the volume of the container when using a fluid that is gaseous or an aqueous liquid at room temperature.

According to a further preferred embodiment of the device according to the invention, the means for generating the alternating electromagnetic field comprise an electromagnetic transmitter and / or a number of electromagnets, the field strength of which is variable, and / or a number with respect to the disinfection units movable constant magnets (including electromagnets) and / or means for causing the disinfecting means to move relative to static constant magnets (including electromagnets), for example by using an alternating flow rate of the fluid in a fluidized bed, and combinations thereof. When using an electromagnetic transmitter or electromagnets, electrical energy can be used to generate the induction voltage in the electrical conductor. When using permanent magnets, mechanical energy can be used to generate the induction voltage in the electrical conductor. The mechanical energy can be supplied, for example, by muscle power, for example by shaking or by driving a rotatable shaft, wind power or water power, for example by driving a rotatable shaft.

Regardless of the manner in which the alternating electric field and / or the alternating magnetic field (including the radio wave) is generated, the coils in the secondary circuit are adapted in a number of embodiments to capture the energy emitted by the primary circuit.

According to a further preferred embodiment of the device according to the invention, the disinfection units are interconnected in a number of networks, such as a number of one-dimensional networks, a number of two-dimensional networks and / or a number of three-dimensional networks. One dimensional networks include strands. Two-dimensional and three-dimensional networks include, for example, meshwork and multi-layer meshwork with cross connections.

According to a further aspect the invention relates to the disinfection unit used in the device according to the invention. The disinfection unit comprises an electrical conductor suitable for generating an induction voltage in an alternating electric and / or magnetic field and an electrically driven disinfectant 20 electrically connected to the electrical conductor, selected from a UV light source, a number of electrolytic electrodes, a number of alternating voltage electrodes and further optional electrical switching components electrically connected to the electrical conductor and the disinfectant and an optional housing for the electrical conductor, the disinfectant and the further optional electrical switching components. Preferred embodiments of the disinfection unit are shown in the subclaims and have already been discussed in connection with the device for disinfecting a fluid according to the invention.

A further aspect of the present invention is directed to a method for disinfecting a fluid, for example water, such as surface water. With the aid of a water treatment method according to the invention, it is possible to disinfect water in both a bulk water production process and in a decentralized water treatment. With the present invention, the scale of decentralized water treatment technology can be chosen so small that a hand-operated disinfection device can make water suitable for human consumption.

10

It is advantageous here that, with a good selection of the components used, the service life of the disinfection device can be particularly long and the investment costs in the disinfection device can remain particularly low.

According to a further aspect the invention relates to a device 5 comprising a substantially plate-shaped body with on one side a number of photovoltaic cells and on the other side a number of disinfection units comprising a number of disinfectant electrically connected to the photovoltaic cells selected from UV light sources, electrolytic capacitors or alternating current electrodes or a combination thereof and wherein the mass / volume displacement of the device is smaller than that of water. This device can also be used for the disinfection of water.

It will be clear to the skilled person that the application of the invention offers unprecedented possibilities for applying disinfection in a sustainable manner without chemicals. And that although all of the concepts described above focus in particular on disinfecting drinking water, the invention can be used more widely. The same embodiments can, for example, also be used for all kinds of other photochemical, photobacteriological and electrochemical processes. Mention may be made, for example, of the formation of radicals in a colloidal mixture of water with Titanium dioxide.

The invention will now be further elucidated with reference to the following example and the enclosed figures, which give non-limitative exemplary embodiments of the invention.

The basic idea of a number of embodiments of the invention is that the UV light is introduced deep into the water. This is done in one embodiment by a small transparent marble in which at least one UV LED is arranged. The LED is electrically connected to a coil that is wrapped around a ferrite core. This is shown diagrammatically in Figure 1 where (1) indicates the UV LED, connected to a coil (2) wound around a ferrite core (3) while the whole is cast in a UV-resistant and UV-permeable synthetic resin (4) here indicated in the form of a marble.

Figure 2 shows an additional UV LED (5) that is connected in the opposite direction to LED nr (1). The light bulb described is supplied with energy by means of an alternating magnetic field or a radio wave. Due to the said counter-connection, one LED is supplied with energy during the plus phase and the other 11 in the minus phase.

This is shown schematically in Figure 3. The marble is composed in such a way that the volume weight is equal to that of water.

Because the LED marbles described are so small, they have a large relative surface. This large area is favorable for the entry of UV light into the water.

Figure 4 shows the holder where the light marbles are located. The water supply pipe (6) progresses gradually until a widening (7) closed on both sides with a grid (8) to stop the light marbles (9). The part of the holder (7) consists of plastic, while the gratings (8) are made of metal.

Figure 5 shows the situation that the water starts to flow (10). The marbles (11) start to float like in a fluidized bed and the water flows past the marbles. A very large internal surface area has thus been created.

In order to provide the light marbles with energy so that UV light is created, an additional housing (12) is provided around the holder, the outside and covers of which are made of metal, while the covers are electrically connected to the gratings (8). This creates a Faraday cage. A radio wave is generated in the housing (12) which supplies the light marbles with energy. Through the Faraday cage 20, the signal is limited to the space where the energy is needed.

An alternative method to provide the light marbles with energy is to provide an alternating magnetic field in the space (12). This is possible through electricity, but also through a number of permanent magnets rotating around.

Figure 6 shows a variant of the fluid bed method described above. As an alternative, the LEDs can be accommodated in a fixed matrix so that a labyrinth is created through which the water can flow.

Figure 7 shows another possible alternative in which a LED strip is rolled up or crumpled internally in a certain way, which also creates a labyrinth. In the solution indicated in Figs. 6 and 7, the energy supply may be the same as for solution in Fig. 5, but it is also possible to make a normal electrical connection by means of wires inserted through the wall.

Figure 8 shows a small-scale application consisting of an inner jug (13) and an outer jug (14). The inner jug is filled with a matrix of 12 fixed light marbles (15) as described in Figure 6. A magnet configuration (16) is slidably arranged in the space between the inner jug and the outer jug that can be moved up and down by shaking and thus a current induces in the marbles. At the top and bottom of the annular space between the inner and outer jug is a rubber block with the function of shock absorber. The inner jug is sealed watertight by a lid. Not indicated is a safety device that ensures that shaking can only take place when the lid is on the jug, this to prevent people from looking into the UV radiation.

As an alternative to the handshaker, a magnet configuration 10 is indicated in Figure 9 which is driven as a manual coffee grinder. The magnet configuration rotates in the space between the inside of the outside jug. It is difficult to turn when the lid is on the jug.

Wherever the fluid bed light marbles or the matrix and the rolled-up LED strip were discussed above, light cubes of a shape that provide sufficient flow even with the closest gasket can also be envisaged. As a result, it is no longer necessary to make the light cubes weight neutral. For the optimum shape of the light cubes, reference can be made to breakwater elements such as Dolossen, Akmons and Tetrapoden. Although these are units used in the gross material world of port works, the principle of a high permeability is the same, but the scale is different.

Figure 10 schematically shows a solution for disinfecting a drinking water tank where there is rotation, for example of a windmill, water power, an (electric) motor or manual power. Within the stator (19) consisting of permanent magnets, the rotor (20) rotates which consists of a number of UV LEDs with an integrated coil with a ferrite core. Via the shaft (21) the rotor is moved in a rotating movement, so that the UV LEDs light up and ensure disinfection. Due to the design of the rotor and the internal guide (22), the water will circulate internally and over time all the water will pass the UV LEDs once to be disinfected.

Figure 11 shows schematically a photovoltaic panel (23) provided on the underside with UV LEDs (24). The whole has been designed in such a way that it is self-floating. It can be placed in the water as a panel and automatically ensures a cleaning effect of, for example, standing water. Where the sun normally causes warming and therefore rich bacterial growth in 13 stagnant water, the sun is used as a disinfection with this configuration. There are no moving parts, everything is solid state and therefore there is hardly any maintenance.

Figure 12 shows a further alternative embodiment of the disinfection unit according to the invention. This embodiment has a plurality of UV-5 LEDs that partially protrude from the housing.

Figures 13a-13c show a number of circuits that can be used in the disinfection units according to the invention using direct current electrodes. The use of a core in the coil is advantageous but not necessary. The circuit of Figure 1c is a circuit analogous to a crystal receiver.

Example

A primary coil is wound around a PVC cylinder with a diameter of 4 cm and a height of 5 cm with 12 turns of 0.8 mm enamelled copper wire. The primary coil is connected to a class A switched output stage of a transmitter that is fed by a 7 MHz Colpitts oscillator. The secondary circuit consists of a coil with 18 turns, 0.7 mm enamelled copper wire on a ferrite core with a diameter of 4 mm and a length of 18 mm. The properties of the ferrite core are such that the inductivity of the coil is 5.8 μΗ. The coil in the secondary circuit is connected to a 5 mm LED and placed in the PVC cylinder. The cylinder is then filled with water. After switching on the transmitter, the LED in the secondary circuit appears to light brightly and, depending on the position of the secondary circuit relative to the primary coil, the LED lights up brighter or less brightly. It is clear to those skilled in the art that the conditions used in this example are far from optimal and that optimization of the primary circuit, the secondary circuit, the applied frequency and tuning of the primary circuit to the secondary circuit is possible. However, the example clearly demonstrates that the technology according to the present invention is applicable in practice and that the dimensions of a secondary circuit are sufficiently small to realize a bed of secondary circuits fluidized in the water to be treated.

In another preferred embodiment, the technology of the present invention is used to remove ions from a liquid by capacitive deionization. For this purpose a packed or fluidized bed of individual particles is used, each containing 2 electrodes with a very large specific surface area. Such electrodes can for instance be manufactured from activated carbon. Each individual particle further preferably comprises a coil, one or more diodes and optionally a capacitor. By making use of induction, each individual particle is supplied with current and, since the diodes used are direct current, both electrodes will be charged, with the result that the electrodes are charged with ions from the liquid. In this way, unwanted ions can be removed from a liquid while there is very intensive contact between liquid and electrode surface. Thanks to the use of a fluidised bed of particles, the system is insensitive to contamination and it is also possible to treat liquids that lead to clogging in traditional capacitive deionization systems. Another positive effect that involves the use of large surface area electrodes in combination with the present invention is that traces of unwanted or toxic organic components adsorb to the surface of the electrode. If the applied voltage on the primary induction coil, which drives the individual particles, is chosen so high that electrolysis also occurs at the electrodes with a large specific surface area, radicals are formed at the electrode surface, which radicals are subsequently adhered to the surface adsorbed traces of organic components. This makes it possible to remove traces of organic contaminants in an energy-efficient manner despite the fact that both the concentration of these substances in the reaction mixture and the concentration of radicals in the reaction mixture are low.

25

In another preferred embodiment, the technology of the present invention is used in combination with LEDs that emit light in the visible area. In this way a reactor for the cultivation of algae or other organisms with photosynthesis is obtained with a very high production rate per unit volume of water. Furthermore, since the wavelength of the light emitted by the LEDs can also be adjusted to the optimum wavelength for growth of the algae or other organisms with photosynthesis, the present technology combines a high production speed per unit volume of water with a high energy efficiency. It is further noted that the mechanical strength of LEDs relative to other lamps such as incandescent lamps, fluorescent lamps is very large and the service life is considerably longer. It is clear to those skilled in the art that an algae reactor according to the technology of the present invention can be further combined with capacitive deionization, disinfection and electrolysis according to the present invention. This is easily done by mixing the LED particles with particles for capacitive deionization, disinfection and electrolysis. By using such combinations, it is possible to influence the composition of the water in which the algae grow, i.e., the dissolved ion content and / or the nature and concentration of microorganisms present. As a non-limiting example, it is stated that, by temporarily adjusting the composition of the water just before harvesting the algae to a desired level, a greater purity of the algae and thus a superior production quality compared to traditional processes are obtained. Furthermore, it is clear to those skilled in the art that a packed bed with a network of LEDs, which are supplied with energy by means of traditional electricity wires instead of by induction, is an efficient lighting technology. Such a packed bed of LEDs can also be combined with a fluidized or non-fluidized bed of small particles which remove and / or disinfect and / or electrolyze ions dissolved or not via induction according to the present invention. Such configurations explicitly form part of the present invention.

1035089

Claims (16)

1. Device for disinfecting a fluid, comprising a holder for holding a fluid, with at least one inlet for introducing the fluid to be disinfected and at least one outlet for removing disinfected fluid and a number further placed in the holder disinfection units comprising a disinfectant selected from UV light sources, direct voltage electrodes or alternating voltage electrodes or a combination thereof, characterized in that the disinfection units are packed in the volume of the container. 2. Device as claimed in claim 1, wherein each disinfection unit comprises an electrical conductor suitable for generating an induction voltage in an alternating electric field and / or an alternating magnetic field and a disinfectant electrically connected to the electric conductor selected from a UV light source , a plurality of direct voltage electrodes, a plurality of alternating voltage electrodes and further optionally electrically connected electrical circuit components connected to the electrical conductor and the disinfectant and an optional housing for the electrical conductor, the disinfectant and the further optional electrical switching components and furthermore the device comprises means for generating of an alternating electric field and / or alternating magnetic field suitable for generating an induction voltage in the electrical conductor of the disinfection units. Device as claimed in claim 2, wherein the electrical conductor is a coil-like wound electrically conductive wire, such as a copper wire, and is preferably an electrically conductive wire wound around a ferrite core. Device as claimed in any of the claims 1-2, wherein the 1035089 disinfectant is selected as a UV light source, preferably a UV LED. 5. Device as claimed in any of the claims 2-4, wherein the disinfectant is selected as an electrolytic capacitor and the further optional electrical switching components are present and these comprise a rectifier bridge or a diode. 5 Conclusions Device according to any of claims 2-5, wherein the disinfection units have a mass / volume displacement of 0.1-1.2 g / cm3, such as 0.4-1.2 or 0.5-1.1 or Have 0.6-1.0 or 0.7-1.0, or 0.8-1.0, or 0.9-1.0 g / cm 3. Device according to claim 2, wherein the means for generating the alternating electromagnetic field comprises an electromagnetic transmitter and / or a number of permanent magnets movable relative to the disinfection units. 15 Device as claimed in any of the claims 1-7, wherein the disinfection units are interconnected in a number of networks, such as a number of one-dimensional networks, a number of two-dimensional networks and / or a number of three-dimensional networks. 20 9. Disinfection unit comprising an electrical conductor suitable for generating an induction voltage in an alternating electric field and / or alternating magnetic field and a disinfectant electrically connected to the electric conductor selected from a UV light source, a number of electrolytic electrodes, a number of alternating voltage electrodes and further optional electrical switching components electrically connected to the electrical conductor and the disinfectant and an optional housing for the electrical conductor, the disinfectant and the further optional electrical switching components. 30 A disinfection unit according to claim 9, wherein the electrical conductor is a coil-like wound electrically conductive wire, preferably a copper wire, and is preferably an electrically conductive wire wound around a ferrite core. A disinfection unit according to any of claims 9-10, wherein the disinfectant is selected as a UV light source, preferably a UV LED. 12. A disinfection unit according to any one of claims 9-11, wherein the disinfectant is selected as a direct-current electrode pair and the further optional electrical switching components are present and these comprise a rectifier bridge or a diode. 13. Disinfection unit according to any of claims 9-12, with a mass / volume displacement of 0.1-1.2 g / cm3, such as 0.4-1.2 or 0.5-1.1 or 0 , 6-1.0 or 0.7-1.0, or 0.8-1.0, or 0.9-1.0 g / cm 3. A method of disinfecting a fluid comprising: (i) providing a device according to any of claims 1-8; (Ii) introducing fluid to be disinfected into the container via the inlet; (iii) generating the alternating electromagnetic field with the aid of the means for this; (iv) removing disinfected fluid through the outlet from the container; 20 15. Method according to claim 14, wherein the fluid to be disinfected is selected from the group of water, such as surface water, spring water or ground water, process water from the beer industry, waste water or sewage water, or a gas stream from a hospital venting system or from a venting system from the organic industry. 16. Device comprising a substantially plate-shaped body with on one side a number of photovoltaic cells and on the other side a number of disinfection units comprising a number of disinfectant electrically connected to the photovoltaic cells selected from UV light sources, electrolytic capacitors or alternating current electrodes or a combination of these and wherein the mass / volume displacement of the device is smaller than that of water. 1035089