NL1039614A - METHOD AND DEVICE FOR DISINFECTION OF A FLUID IN AN INDUCTION REACTOR WITH A LIGHT SOURCE AND TITANIUM OXIDE PARTS AND OZONE. - Google Patents

Description

Method and device for disinfecting a fluid in an induction reactor with a light source and titanium oxide particles and ozone

The present invention relates to a method and device for disinfecting a fluid and a method for disinfecting a fluid. The device comprises a container for holding a fluid, with at least one inlet for introducing the fluid to be disinfected and at least one outlet for removing the disinfected fluid and further placed in the container and / or fluidized in the container, a number of disinfection units comprising at least a disinfection unit from the group of conductive bodies for generating eddy currents in and / or around these bodies and / or conducting bodies coated with titanium oxide and in which eddy currents can be generated and / or non-conducting bodies coated with titanium oxide. In the conducting bodies for generating eddy currents, these eddy currents are preferably generated by means of induction, i.e., by subjecting these bodies to an alternating magnetic field.

preface

The present invention relates to a device for treating a fluid, for example water, for cleaning and / or disinfecting it.

According to the state of the art, a method and device are known for treating a fluid in which a container with at least one inlet and an outlet for respectively introducing a fluid to be disinfected and discharging a fluid to be disinfected is packed and / or fluidized with particles. The container preferably consists of a cylindrical reactor and the particles in the container are supplied with energy by means of induction. For this purpose, a first alternating current source is preferably operatively connected to a first coil which is wound around the preferably cylindrical reactor. According to the prior art, the particles comprise means for converting the alternating magnetic field generated by the first alternating current source and first coil into an induction voltage and induction current in the particles contained in the container. This is done by means of a coil located in the alternating magnetic field that is generated by the first current source and the first coil. An accurate description of this state-of-the-art technology is shown in Dutch patent application NL1035089.

The present invention relates to a method and device for treating a fluid and / or its disinfection according to the technology as described in NL1035089 in which a new type of particles is used in the packed bed and / or fluidized bed. The process and the device with the new type of particles is characterized by robustness of the particles, mechanical stability, low production costs, low investment costs and high energy efficiency of the disinfection process.

Description of the technology according to the present invention

According to a first aspect, the technology according to the present invention consists of a container with at least one inlet for the fluid to be treated and an outlet for the treated fluid. The holder is preferably a cylinder.

According to a second aspect, the technology according to the present invention consists of particles placed in the holder in the form of a packed bed and / or a fluidized bed.

According to a third aspect of the present invention, the container contains particles consisting of metallic geometric shapes and / or titanium oxide coated metallic geometric shapes and / or non-metallic but conductive geometric shapes such as carbon or graphite and / or titanium oxide coated non-conductors with a characteristic diameter and / or hydraulic diameter in the range of 0.1 mm to 1 meter, more preferably in the range of 1 mm to 50 cm, even more preferably in the range of 5 mm to 20 cm and most preferably in the range of 1 cm to 10 cm. If metal is used, this preferably consists of stainless steel and / or iron and / or copper and / or silver and / or gold and / or platinum and / or titanium and / or lead and / or tin and / or aluminum and / or magnesium and / or zinc and / or titanium and / or manganese and / or vanadium.

In a fourth aspect of the present invention, the container optionally includes disinfectants including ozone produced in a separate ozone generator and dosed to the container, ultrasonic transducers operatively connected to the container, for example by attaching it to the container by means of a screw cap gas discharge lamps mounted in the holder using a prior art gas discharge lamp including UVC lamps, LEDs including LEDs producing UVC and / or LEDs producing light with a wavelength of less than 500 nm, electrodes made of a material according to The prior art is used for electrolysis, such as titanium oxide coated material, antennas and / or electrodes which are operatively connected to an electromagnetic transmitter and / or a current source and / or an alternating current generator superimposed on a direct voltage. The combination of the additional disinfectants described in this fourth aspect with the technology according to the present invention appears to have unexpected very large synergistic effects with the technology according to the present invention. Without making any limitation in the scope of the technology according to the present invention, the inventors of the present invention have the following explanation for this synergy: The additional disinfectants already weaken and / or kill part of the organisms present in the fluid and / or or already oxidize a part of the undesired components present in the fluid. In addition to this effect, the following additional synergistic effects with the technology according to the present invention appear to occur: 1. The weakened microorganisms and / or cysts and / or worms (eggs) move substantially in plug flow through the packed and / or fluidized bed. This means that as a function of the length of the reactor, the residence time of these organisms increases and that the residence time spread is minimal. In short, there are no preferential flows in the reactor. This means that each microorganism is treated with the disinfection technologies according to the present invention for a precisely defined time. The result of this is a very reliable disinfection reactor that can be accurately dimensioned based on packed and / or fluidized bed technology.

2. If ozone is dosed as a disinfecting component, this ozone will react as a function of the length coordinate of the reactor and have its disinfecting effect. Since there is hardly any residence time distribution in the reactor, it is possible to dose exactly so much ozone that the ozone concentration at the outlet of the reactor is virtually zero. In that case, no or only a very small separate ozone degradation unit has to be built. Not only does this result in high energy efficiency, but also in lower investments and a lower consumption of active carbon to destroy the excess ozone.

3. The packed and / or fluidized particles have a large specific surface area and come into intensive contact with the organisms to be killed. This leads to a great efficiency of the process.

4. In case the holder is operatively connected to one or more ultrasonic transducers, the particles defined in the third aspect will vibrate. This increases the disinfecting effect of these particles. In case the particles consist of a conductor, the disinfecting effect is increased since on the surface of the particles both eddy currents arise which have a disinfecting effect on the microorganisms and there are ultrasonic vibrations. The effects of eddy current and ultrasonic vibrations are synergistic. This means that the disinfection with both combined technologies is more effective per Watt electrical power than with each of the two technologies separately.

5. If particles are also present in the holder that contain titanium oxide, radicals will be formed on the surface of the titanium oxide under the influence of ultrasonic vibrations and under the influence of eddy currents.

6. If the container contains any light source, radicals will also form on the surface of the titanium oxide under the influence of the light (preferably UV light but not limited to it). The effects under points 4, 5 and 6 are synergistic.

7. If the container contains an antenna, the system of particles in water will behave as a part of this antenna, resulting in disinfection. The effects under points 4, 5, 6 and 7 are also synergistic.

8. The particles constantly collide with each other in a fluidized bed. This keeps them clean and the collisions also have secondary eddy current effects that appear to have a very favorable effect on the disinfection process.

Now that the most important aspects of the technology according to the present invention have been described, a number of preferred embodiments follow.

In a first embodiment, the technology according to the present invention consists of a cylinder with a first coil wound around it. The first coil is supplied with electrical energy through a first alternating current source. Stainless steel particles are introduced into the cylinder. These particles are preferably cylindrical and hollow. The consequence of the presence of the first alternating current source and the first coil is that an alternating magnetic field is created in the cylinder. This results in eddy currents in the cylindrical metal particles. The result of this is that micro-organisms in a liquid that flows past these particles are exposed to an alternating electric field. As a result, the cell membrane of the microorganisms is weakened and / or destroyed and disinfection occurs.

In a second embodiment, at least a part of the metal particles in the first embodiment is provided with some coating containing titanium oxide. This coating containing titanium oxide ensures the production of radicals under the influence of eddy currents and / or under the influence of any ultrasonic vibrations which are introduced into the holder and / or under the influence of light introduced into the holder.

Particularly suitable particles coated as titanium oxide are metal plates which according to the state of the art are used as electrodes in chlorine electrolysis. Such plates can be cut into pieces and inserted as particles into the reactor according to the technology of the present invention.

In a third embodiment, one or more of the previous embodiments one and two are combined with ultrasonic vibrations, UVC light, LED light in the UVC region, LED light with a wavelength of less than 500 nm, alternating current flowing through electrodes arranged in the reactor.

In a fourth embodiment, one or more of the previous embodiments one through three are combined with an ultrasonic technology as described in Dutch patents NL1036046, NL1036416, NL1036982, NL1037278, NL1037277.

In a fifth embodiment, one or more of the previous embodiments one to four are combined with transformer technology and / or switching power supply technology and / or coil technology as described in Dutch patents NL1036082, NL1036092, NL1036509, NL1036981, NL1037277, NL1037278.

In a sixth embodiment, one of the earlier embodiments one through five is combined with radical and / or ozone production technology as described in Dutch patents NL1035556, NL1035555, NL1036414, NL1036984.

In a seventh embodiment, one or more of the previous embodiments one through six are combined with disinfection technologies as detained in the not yet published Dutch patent application NL1037938. By this is meant all possible combinations of the technology in this application with the technology in NL1037938 and preferably the following passages in application NL1037938: According to a first aspect of NL1037938, the technology according to the present invention makes use of vibrations. In this application, vibrations are understood to be: acoustic vibrations including ultrasonic vibrations, electromagnetic vibrations including light and radio waves, alternating current, an alternating electric and / or magnetic field, pulsed acoustic vibrations, pulsed electromagnetic vibrations, pulsed alternating current (so-called wave trains), pulsed direct current and / or a pulsed electric and / or magnetic field as well as combinations of one or more of these vibrations. Concrete non-limiting interpretations of such vibrations are UVC light produced by UVC gas discharge lamps, radio waves produced by electromagnetic transmitters that produce at least carrier waves lying in the frequency range between 10 kHz and 3 GHz and function generators with an amplifier coupled thereto including single-ended amplifiers.

According to a second aspect of NL1037938, the present invention consists of means for generating these vibrations. The means for generating the vibrations preferably comprise at least one microprocessor, such as a microcontroller, which software-sets the nature of the vibrations. Even more preferably, the microcontroller not only controls the generator of the vibrations with software but also controls the operation of process equipment. Non-limiting examples are a coffee maker and a purifier for the production of drinking water. In these devices, a series of actions are performed in software where heat exchangers are switched on and / or valves are controlled and / or sensors are read out as soon as the function of the devices is invoked. A similar situation applies in the process industry in, for example, the control of drinking water purification plants in general and membrane plants for water purification in particular.

According to a third aspect of NL1037938, the present invention consists of means for applying a combination of vibrations to prevent scaling and / or biofouling and / or effect disinfection. As non-limiting types of vibrations for the realization of combinations of vibrations are mentioned: ultrasonic vibrations, (JVC radiation, vibrations that influence the surface of a Ti02 coating such as electromagnetic radiation and ultrasonic vibrations, alternating current in the frequency range from 0.01 Hz to 100 Hz, alternating current in the frequency range from 100 Hz to 1 MHz, alternating current in the frequency range from 1 MHz to 10 GHz, alternating electric fields, alternating magnetic fields, pulsed electromagnetic vibrations, pulsed alternating current (so-called wave trains), pulsed direct current and / or a pulsed electric and / or magnetic field as well as combinations of one or more of these vibrations.

According to a fourth aspect of NL1037938, the technology of the present invention consists of means for varying the nature of the vibrations during the treatment of the water in order to make use of the fact that different types of microorganisms are sensitive to different frequencies of vibrations to be. In some but not all cases, the occurrence of scaling requires a different composition of the vibrations than the suppression of biofouling or disinfection.

According to a fifth aspect of NL1037938, the technology according to the present invention consists of means for visualizing that a device must be cleaned.

Non-limiting examples of such means are LED indication, acoustic signal, message on a display optionally accompanied with electronic operation of the device to prevent failure of the device to lead to a device failure.

According to a sixth aspect of NL1037938, the technology of the present invention consists of means for automatically or continuously measuring the effectiveness of the vibrations for preventing scaling and / or biofouling and / or for disinfecting water-containing liquid, the measurement results by software interpret in a microprocessor and if necessary adjust the nature of the vibrations to optimize the effectiveness of the treatment and / or to minimize energy consumption.

A first non-limiting example of such a means is a conductivity meter whose electrodes are attached to a preferably non-electrically conductive material whose biofouling and / or scaling must be prevented. A non-limiting example of such a material is the plastic housing of a water purifier through which water to be purified and / or purified flows. If biofouling occurs on the plastic housing of a water purifier, the conductivity of the surface of that housing changes. If the electrodes of a conductivity meter are mounted on the wall of the housing, the occurrence of biofouling can be determined in a simple manner by means of impedance spectroscopy. It is clear to a person skilled in the art that such a measurement can be carried out completely automatically and using software by means of a simple microcontroller with outputs and an ADC input. As soon as the sensor detects the growth of biomass, the nature of the treatment of the water with vibrations can be adjusted. Furthermore, it appears that the conductivity of the surface changes in a different way when scaling occurs compared to the situation that biofouling occurs. It is therefore possible with software to determine the difference between biofouling and scaling on a surface with the conductivity sensor and to automatically tune the treatment of the liquid and the device for treating the liquid with vibrations accordingly. As a non-limiting example of electrodes suitable for mounting on a plastic surface, electrodes with a surface of TiO 2 are mentioned. Such electrodes are used in practice for electrolysis purposes and appear to be highly resistant to scaling, biofouling and corrosion. The impedance spectroscopy preferably takes place in a frequency range between 0.01 Hz and 10 GHz. It is noted that at frequencies above 10 MHz, even contamination of conductive surface such as metal can be measured. It is further noted that suitable means for impedance spectroscopy consist of an oscillator driven by the microprocessor. At low frequencies, an alternating voltage can easily be generated by means of a so-called H bridge circuit or a microprocessor-driven push-pull circuit with isolating transformer. At high frequencies an oscillator or a series of oscillators can be switched on by means of the microcontroller, each of which is used as a function generator for impedance spectroscopy.

A second non-limiting example of a sensor for optimizing the nature of the vibrations is an acoustic microphone in general and an ultrasonic microphone in particular. If a water-tight microphone is attached to a surface to be protected with the technology according to the present invention and acoustic vibrations are generated in the vicinity of the surface to be protected, for example by an ultrasonic transducer, the amplitude and the frequency spectrum of the signals recorded in the microphone change as soon as a layer of biofouling and / or scaling forms on the surface to be protected.

A third non-limiting example of a sensor to optimize the nature of the vibrations is a capacitive sensor consisting of 2 or more electrodes, preferably with a TiO 2 surface or an Au surface or a Pt surface. A preferred embodiment are flat plates which are stuck to the surface to be protected against fouling. If surface growth occurs, the dielectric between these plates changes significantly, with the result that the capacitance of the capacitor formed by both plates changes.

A fourth non-limiting example of a sensor to optimize the nature of the vibrations is a turbidity meter.

According to a seventh aspect of NL1037938, the technology according to the present invention consists of means for supplying electrical energy to the vibration-producing transducers. These means consist of a function generator, an amplifier, at least a microcontroller that generates the electrical signal for generating the vibrations by software. If the electrical supply takes place from the public electricity grid, use is preferably made of a new type of electronic circuit with which it is possible to start up the microcontroller without using a transformer. This feed is described in detail in Dutch patent application NL1037613.

Now that the most important aspects of the technology according to the present invention have been described in combination with NL1037938, a number of preferred embodiments follow from NL1037938.

In a first embodiment, a disinfection device is provided with a gas discharge lamp (which produces JVC radiation and disinfects water to be purified which flows through the disinfection device. The walls of the disinfection device are provided with a coating of TiO2. unique situation where the exposure of the titanium oxide to the UVC radiation on the surface of the titanium oxide coated wall creates radicals, which not only considerably increases the efficiency of the UVC disinfection but also prevents biofouling and slime formation in the water disinfection device Preferably, the condition of the wall surface in the disinfection apparatus as previously described is monitored by means of a sensor In a special embodiment, the titanium oxide coating and / or a coating consisting of a semiconductor with a composition other than titanium oxide or a composite of titanium oxide or one titanium oxide enriched with trace elements irradiated with LED lighting. In the case of UVC, the LED lighting emits light with a wavelength (in air) of 254 nm. However, it is known to those skilled in the art that LED illumination operating in the UVC region around 254 nm is still under development and that this illumination is expensive and subject to wear mainly due to the fact that the plastic housing of this illumination is affected by the UVC produced. LED lighting with a larger wavelength, for example 365 nm (in air) is, however, commercially available, inexpensive, energy-efficient and has a long lifespan. In these applications, LED illuminated also means OLEDs. The use of OLEDs has the advantage that the light-emitting surface is large, so that use can be made of titanium dioxide-coated static mixers which are then kept clean with OLEDs and also ensure disinfection of the water flowing in plug stream through the disinfection reactor. Experiments have shown that these LEDs are very capable of activating a titanium oxide coating so that radicals are formed on the surface of this coating. In this way it is possible to use LED lighting that produces radiation with a wavelength considerably larger than 254 nm in a sustainable way for the disinfection of water. It is clear to those skilled in the art that this technology is extremely suitable for disinfecting water at a low voltage, without using quartz tubes, with a comparable efficiency as is achieved with current UVC gas discharge lamps. In addition, the technology according to the present invention is extremely suitable for preventing biofouling on walls coated with titanium oxide-containing coating so that the radicals on the surface arise, i.e., exactly at the place where the biofouling and / or scaling are undesirable.

In a second embodiment from NL1037938, a disinfection device is provided with a gas discharge lamp that produces UVC radiation and disinfects water to be purified that flows through the disinfection device. There is also an ultrasonic transducer in the disinfection device that generates microcavitation through ultrasonic vibrations. Both the UVC radiation and the ultrasonic vibrations individually have a disinfecting effect. Together they have an effect that is greater than the sum of the individual effects (synergistic effect). Due to the ultrasonic vibrations, the walls of the disinfection device appear to remain free of scaling and biofouling and the quartz tube in which the UVC lamp is located remains clean. This ensures optimum disinfection of the disinfection device. It is noted that it is not necessary in practice for the ultrasonic transducer to be driven continuously. Preferably, the disinfection device is equipped with a previously described sensor which is operatively connected to a microcontroller which also controls the UVC lamp and ultrasonic transducer. Intelligent software is used to determine iteratively an on - off time for the transducer, keeping the wall of the disinfection device clean. It is clear to those skilled in the art that the software can be written in such a way that, depending on the quality of the water to be purified, the associated settings of the ultrasonic water treatment are automatically determined. This makes the disinfection device usable in a sustainable way for the purification of a wide range of water qualities.

In a third embodiment from NL1037938, a disinfection device is provided with an ultrasonic transducer. The walls of the disinfection device are provided with a previously described sensor. The amplitude of the ultrasonic vibrations is adjusted so that the liquid is effectively disinfected and at the same time the walls of the device remain clean. If this capacity is not sufficient to also keep the walls of the device clean, the capacity supplied by the ultrasonic transducer is increased by software.

In a fourth embodiment from NL1037938, a disinfection device is provided with a UVC lamp.

The walls of the disinfection device are equipped with the sensor described earlier. The power of the UVC lamp is set so that the liquid is effectively disinfected and at the same time the walls of the device remain clean. It is clear to a person skilled in the art that a minimum UVC capacity is required to disinfect the liquid. If this capacity is not sufficient to also keep the walls of the device clean, the capacity supplied by the UVC lamp will be increased by software.

In a fifth embodiment from NL1037938, a disinfection device is provided with an ultrasonic transducer. The walls of the disinfection device are provided with a previously described sensor. The amplitude of the ultrasonic vibrations is adjusted so that the liquid is effectively disinfected and at the same time the walls of the device remain clean. The walls of the device are coated with titanium oxide. As a result, under the influence of the ultrasonic vibrations radicals are formed on the surface of the titanium oxide, with the result that the walls of the disinfection device remain clean at a lower ultrasonic power compared to the situation that these walls would not be coated with titanium oxide. If the ultrasonic power proves to be insufficient to also keep the walls of the device clean, for example due to a very poor quality of the water to be purified, the power supplied by the ultrasonic transducer is increased by software.

In a sixth embodiment from NL1037938 a disinfection device is provided with electrodes, preferably stainless steel or with a coating of titanium oxide to which an alternating voltage source or alternating current source is connected with a frequency that is preferably in the range of 0.01 Hz to 100 GHz. At least 1 electrode is preferably located against the wall of the disinfection device to prevent biofouling and / or scaling. Even more preferably, not 1 frequency is applied but a frequency range is traversed ("frequency sweep"). The reason for applying a series of frequencies is that different microorganisms appear to be sensitive to alternating currents of different frequencies.

In an eighth embodiment from NL1037938, one of the aforementioned embodiments 1 to 7 is wholly or partly combined with an electrolysis cell arranged in the disinfection apparatus.

So far a number of descriptions of embodiments from Dutch patent application NL1037938 that are particularly suitable for use in combination with the technology according to the present invention

In an eighth embodiment, the particles according to the fourth aspect of the present invention consist of cylinders provided with a metal film, such as, for example, Raschig rings coated with silver.

Claims (17)

An apparatus for disinfecting a fluid, characterized by • a cylindrical reactor with at least one inlet for introducing the fluid to be disinfected and at least one outlet for removing the disinfected fluid • at least one coil arranged around the cylindrical reactor and operatively connected to • a first alternating current source for generating an alternating magnetic field in the cylindrical reactor • a bed of active packing particles that is present in the cylindrical reactor and that is at least partially fluidized in which • the active packing particles are exclusively made of hollow metal cylinders or hollow metal-coated cylinders exist with a length between five millimeters and two hundred millimeters, and therefore do not contain electrodes or electronic components and in which • these active packing particles are at least provided with a titanium oxide coating • eddy currents in the active suit particles due to induction • collisions between the fluidized active packing particles, keeping the particles clean and causing secondary eddy current effects that promote the disinfection process • low residence time distribution of the liquid in the reactor, approximation of plug flow • at least one light source that is installed in the induction reactor and which irradiates at least a part of the surface of the active packing particles coated with titanium oxide with the result that radicals are formed on the surface of the active packing particles and eddy currents occur simultaneously. • at least one ozone generator that is operatively connected to the cylindrical induction reactor and therefore continuously supplies an ozone-containing gas stream to the reactor inlet Device as claimed in claim 1, wherein the active packing particles consist of metal-coated Raschig rings. The device of claim 2 wherein the Raschig rings are coated with both titanium oxide and silver Device as claimed in any of the foregoing claims 1-3, wherein the light source is a UVC radiation-producing gas discharge lamp. The device of claim 4 wherein the (JVC gas discharge lamp produces (JVC radiation with a wavelength of 254 nm.) Device according to one of the preceding claims 1 to 3, wherein the light source consists of UV LEDs that produce electromagnetic radiation with a wavelength greater than 254 nm and less than 500 nm. Device according to claim 6, wherein the light source consists of LEDs that produce electromagnetic radiation with a wavelength of 365 nm. Device according to one of the preceding claims 6 and 7, wherein the LEDs consist of OLEDs. Device as claimed in any of the foregoing claims 1-8, wherein the light source is supplied with electrical energy by means of induction. Device as claimed in any of the foregoing claims 1-9, wherein the active packing particles also contain more than 0.1% by weight of copper. Device according to one of the preceding claims 1 to 10, wherein the active packing particles also contain more than 0.1% by weight of carbon. Device according to one of the preceding claims 1 to 11, wherein the active packing particles also contain more than 1 mg / kg of platinum. Device according to one of the preceding claims 1 to 12, wherein the active packing particles also contain more than 1 mg / kg of gold. Device according to one of the preceding claims 1 to 13, wherein the active packing particles also contain more than 1 mg / kg of palladium. Device according to one of the preceding claims 1 to 14, in which the active packing particles also contain more than 10% by weight of iron. A method for disinfecting a fluid characterized by a device according to one of the preceding claims 1 to 15. A method of disinfecting a fluid according to claim 16, characterized in that no means are used to break down any excess ozone in the liquid stream leaving the reactor outlet.