NL1038115C2 - METHOD AND DEVICE FOR DISINFECTION OF WATER WITH A DC VOLTAGE SUPPLIED VOLTAGE VOLTAGE. - Google Patents

Description

Method and device for disinfecting water with an alternating voltage superimposed on a direct voltage

The present invention relates to a method and device for disinfecting water, characterized by at least a first voltage source, at least means to rectify the voltage supplied by the at least first voltage source, at least means to at least partially level off the rectified voltage and / or allowing the amplitude of the rectified voltage to fluctuate with an adjustable frequency as a function of time, hereinafter referred to as effective voltage, and at least electrodes which are at least partially in water to be disinfected and which are operatively connected to the effective voltage.

preface

A proven and highly effective way to disinfect water in the food industry, process industry, in drinking water treatment plants and waste water treatment plants is the application of electrolysis. According to prior art, this electrolysis is carried out in a liquid containing chloride ions so that active chlorine is produced which has a strong disinfecting effect.

An important advantage of a chlorine electrolysis for disinfection purposes is the great effectiveness of this method and the relatively low cost of the disinfectants compared to other techniques. A disadvantage associated with the production of active chlorine is that not only (micro) organisms are killed, but that organic compounds that are present in the water can be chlorinated. Such chlorinated organic compounds are often toxic and / or have a hormonal effect, as a result of which even very low concentrations of these compounds (in the order of 25 nanograms per liter) are undesirable.

There is a demand in the market for a method of disinfecting water in general and drinking water and waste water in particular, which on the one hand has the effectiveness of state-of-the-art electrolysis and on the other hand does not have the disadvantages of forming chlorinated organic compounds.

The technology according to the present invention relates to a new electrolysis technology that makes it possible to effectively disinfect water and at the same time prevent unwanted chlorinated organic compounds from being formed.

Description of the technology according to the present invention The technology according to the present invention aims to temporarily influence the functioning of cells of living organisms by means of an alternating current and / or an alternating direct current.

1038115 2

According to a first aspect of the technology according to the present invention an alternating current or alternating direct current makes the cells of bacteria including cyanobacteria and / or fungi and / or protozoa and / or algae and / or spores and / or eggs including worm eggs and / or cysts temporary made considerably more sensitive to 5 chemicals, including active chlorine. Eggs and cysts in particular are notorious for their resistance to active chlorine disinfection according to the state of the art and the technology according to the present invention is therefore ideally suited to eggs in general, and eggs occurring in the water such as eggs of to kill shellfish, worms and cysts at a low concentration of active chlorine. Without thereby limiting the scope of the present invention, the inventors of the technology of the present invention have the following explanation for the perceived high sensitivity of living cells to chemicals in the event that these cells are exposed to an alternating current and / or alternating direct current: due to the alternating current and / or alternating direct current in the liquid in which the cells are located, the permeability of the cell membrane of the cells changes temporarily, with the result that chemicals end up in the cell faster and with a higher concentration. As a result, when applying electrolysis, the minimum amount of active chlorine required to disinfect water is lower than in the absence of the alternating voltage or alternating direct voltage.

According to a second aspect, the technology according to the present invention makes use of electrodes which are at least partially in contact with the water to be disinfected and which are operatively connected to a current source which transmits the alternating current or alternating direct current through the contact surface of the electrodes with the water. directs the water.

According to a third aspect, the electrodes according to the technology of the present invention consist of a conductive material which is stable under the applied process conditions and / or corrodes or reacts away at an acceptable speed and thus serves as a sacrificial electrode. A non-limiting example of conductive material that is stable under the applied process conditions is metal that is provided with a titanium oxide coating. A non-limiting example of conductive material that acts as a sacrificial electrode under the applied process conditions is carbon or active carbon or a composite of carbon or a composite of active carbon. Another non-limiting example of conductive material that functions as sacrificial electrode under the applied process conditions is an anode which consists at least in part of copper and / or silver or of a composite material containing salts or oxides of these metals. It is known to those skilled in the art that copper ions and silver ions have a disinfecting effect. If such metals are used in an electrode of an electrolysis process that is used as a sacrificial electrode, a triple disinfecting effect can be obtained according to the technology according to the present invention: the alternating current and / or alternating direct current disrupts the function of the organism to be killed so that this organism is killed. becomes more sensitive to 5 disinfecting chemicals; active chlorine is formed which, thanks to the alternating current and / or alternating direct current, already effectively disinfects at low concentrations; copper ions and silver ions are formed which also have a disinfecting effect at a low concentration.

According to a fourth aspect, the technology according to the present invention consists of 10 means for generating an alternating direct voltage. Use is made for this purpose of at least a first power source. This first power source consists of a battery or accumulator. The first power supply may also consist of a generator such as a wind turbine or a water turbine that generates an alternating voltage which is then at least partially rectified. Optionally the at least rectified supply voltage 15 is used to charge a battery or accumulator. Furthermore, the first power supply may also consist of a device fed by the mains. Such a supply source preferably comprises at least one isolating transformer and power diodes for rectifying the alternating voltage. Even more preferably, the rectified alternating voltage is at least partially flattened with a capacitor. Most preferably, this capacitor is a parallel circuit of an electrolytic capacitor and a ceramic capacitor or an unpolarized capacitor with similar properties to a ceramic capacitor. Even more preferably, at least one choke is included in the rectifier circuit to minimize the amplitude of interfering alternating voltages.

According to a fifth aspect, the technology of the present invention consists of a microcontroller. This microcontroller is used to alternately switch the current supplied by the first power source on and off with a software-adjustable frequency. This can be realized, for example, by alternately switching a power FET, which is operatively connected to the first power supply, on and off with a microcontroller. A major advantage of using a microcontroller for this purpose is that the frequency of the pulsed direct voltage can be adjusted by software. Extensive research into the effectiveness of pulsed direct current for killing micro-organisms has shown that different types of micro-organisms are sensitive to different frequencies. As a result, for a number of applications it is important to expose the water to be treated to an alternating current and / or alternating direct current with different frequencies. This can be achieved through the application of a microcontroller through software.

4

According to a sixth aspect, the technology according to the present invention consists of an electrolysis reactor which has only a limited volume, i.e., in which the liquid to be treated remains only for a limited time. Preferably, the liquid to be disinfected remains in the electrolysis reactor for less than 1 hour. More preferably, the liquid to be disinfected remains in the electrolysis reactor for less than 10 minutes. Even more preferably, the liquid to be disinfected remains in the electrolysis reactor for less than 1 minute. Most preferably, the liquid to be disinfected remains in the electrolysis reactor for less than 10 seconds. The reason that the technology according to the present invention is particularly suitable for disinfecting liquid in an electrolysis reactor with a short residence time is that in the reactor the function of the organisms to be disinfected is disturbed by the use of the alternating current and / or alternating direct current. One of the consequences of the alternating current and / or alternating direct current is that the cell membrane of the organisms becomes temporarily permeable. Since active chlorine is also formed in the electrolysis reactor, this can quickly penetrate the cell (s) of the microorganisms present in the liquid. As a result, a lethal dose of chlorine is introduced into the reactor into the organism, which subsequently dies either outside the reactor or after the chlorine has acted. It is noted that a cell or cell membrane disrupted by the alternating current and / or alternating direct current is increased for some time to be sensitive to chemicals in the immediate vicinity of that cell. As a result, it is quite possible that the intended effects of active chlorine and the treatment with alternating current and / or alternating direct current occur outside the electrolysis cell. It is clear to the skilled person that thanks to the technology according to the present invention, disinfection of liquids is possible in considerably smaller reactors with a smaller electrode area than is necessary in the prior art. It is also clear to the skilled person that the amount of energy per 25 cubic meters of water required for disinfecting that water with the technology according to the present invention is considerably smaller than the energy consumption with electrolysis technology according to the prior art.

According to a seventh aspect, the technology according to the present invention consists of at least one capacitor which is connected in parallel to the electrodes used for electrolysis. If a pulsed direct current source is operatively connected to the electrodes to which the capacitor is connected in parallel, a direct voltage will arise on which an alternating voltage is superimposed (alternating current over direct current or hereinafter referred to as AC over DC). A large number of experiments have shown that this method is an inexpensive and very reliable method for realizing AC over DC. Since the frequency of the alternating current component is preferably in the range between 10 kHz and 1 MHz, a capacitor of limited capacity can suffice. Furthermore, by using the parallel connection of the electrodes and the capacitor, it is possible to realize AC over DC with relatively simple electronic means and a high energy efficiency. As a result, a durable and reliable AC over DC device can be realized at a relatively low cost price, the electrical properties of which can be adjusted both by software and by the choice of the capacitor.

Now that the core of the technology according to the present invention has been explained, a number of non-limiting embodiments are elaborated.

In a first embodiment, the technology of the present invention is combined with UVC disinfection technology. For this purpose, first a micro-organism 10 with AC or AC over DC is temporarily weakened, after which the micro-organism is exposed to UVC radiation. It is noted that the UVC radiation works in 2 ways: the radiation destroys DNA and RNA as well as proteins and the radiation generates radicals and / or ozone that can penetrate the microorganism more quickly. The first treatment with UVC and then AC and / or AC over DC is expressly part of the technology according to the present invention.

In a second embodiment, the technology according to the present invention is combined with ultrasonic vibrations. For this purpose, the water to be treated is preferably first exposed to ultrasonic vibrations. A first important effect of the ultrasonic vibrations is that aggregates of particles in the water to be treated are broken up into smaller aggregates or and / or individual particles under the influence of the ultrasonic vibrations. The consequence of this is that living organisms that were, as it were, encapsulated in organic and / or inorganic particles are thereby accessible for active chlorine and / or AC and / or AC over DC. A second important effect of the ultrasonic vibrations is that the function of the living organisms is disturbed by the ultrasonic vibrations, this in analogy with the AC and / or AC over DC. It is known in the literature that microcavitation ultrasonic vibrations can produce radicals and also provide electroporation. It follows that ultrasonic treatment of water is a technology that is eminently suitable for use in combination with the technology according to the present invention. A synergistic effect occurs, which means that disinfection is possible with less electrical energy and fewer chemicals than if only the ultrasonic treatment or only the AC over DC treatment were applied. From the foregoing it appears that also first treating with AC over DC and then applying ultrasonic vibrations can lead to a synergistic effect. This order of treatment is therefore expressly part of the technology according to the present invention.

In a third embodiment, the technology according to the present invention is combined with exposing the liquid to be treated to radio waves and / or a high-frequency alternating current with a frequency in the range of 10 kHz to 10 GHz.

6

Even more preferably, it relates to amplitude modulated or frequency modulated radio waves with a carrier frequency in the range of 100 kHz to 100 MHz and a frequency of modulation from 1 kHz to 1 MHz. Most preferably, a carrier frequency in the range of 50 kHz to 5 MHz is used and a frequency of the modulation in the range of 1 kHz to 1 MHz.

In a fourth embodiment, the technology of the present invention is combined with dosing of ozone.

In a fifth embodiment, the technology according to the present invention is combined with UV disinfection by means of LEDs, it being noted that these 10 LEDs produce no or hardly any UVC with light with a longer wavelength. Thanks to the synergy with the technology according to the present invention, this LED disinfection is very effective despite the longer applied wavelength.

In a sixth embodiment, the technology of the present invention is combined with chlorine dioxide disinfection.

In a seventh embodiment, the AC over DC technology according to the present invention is combined with at least 2 disinfection technologies from the group of ultrasonic disinfection, disinfection with radio waves and / or high-frequency alternating current, UVC disinfection, LED UV disinfection, disinfection with ozone, disinfection with chlorine dioxide.

In an eighth embodiment the technology according to one of the previous embodiments one to seven is used for disinfecting drinking water.

In a ninth embodiment the technology according to one of the previous embodiments is used up to and including seven for disinfecting waste water including sewage and waste water from hospitals.

In a tenth embodiment, the technology according to one of the previous embodiments, one to seven, is used for disinfecting foodstuffs such as fruit juices, milk products, beer, wine, but not limited thereto.

In an eleventh embodiment the technology according to one of the previous embodiments is used up to and including seven for disinfection of installations that come into contact with foodstuffs such as equipment in dairy factories, beer breweries, fruit juice factories, but not limited thereto.

In a twelfth embodiment the technology according to one of the previous embodiments is used up to and including seven for disinfecting water in cooling installations, cooling towers, ballast water in ships.

Now that the core of the technology according to the present invention has been explained as well as the scope of application has been described, it is further elaborated on the device that makes it possible to use AC over DC in practice.

As will become clear in the following text, the AC over DC technology i 7 consists of unique process technology concepts that can be used instead of or in combination with disinfection technologies according to the state of the art and of an electrical design that, thanks to the applied disinfection mechanism can be surprisingly simple. Both the process technology concepts and the electrical engineering design of the AC over DC technology form a separate and jointly explicit part of the technology according to the present invention.

When designing and realizing the electrical installation for treating water with AC over DC, at least the following 10 aspects must be taken into account: • No high-frequency interference may be brought into the network.

• The installation must not work as an antenna and generate disturbing electromagnetic radiation.

• The installation must be suitable for large capacities and large currents, i.e. 15 currents up to 300 Ampere.

• Depending on the composition of the liquid to be disinfected (conductivity of the liquid), the voltage across the electrodes must be adjusted automatically so that the desired current flows through the water and thus the correct amount of active chlorine is produced.

· The frequency of the AC component that is superimposed on the DC must be software-adjustable.

• The amplitude of the AC component that is superimposed on the DC must be able to be set to an optimum value for each application.

It is clear to a person skilled in the art that only by designing a device specially designed for the AC over DC technology according to the present invention can the above design criteria satisfy. Furthermore, it is clear to those skilled in the art that commercially available switching power supplies are not easily adaptable so that they are suitable for AC over DC applications.

After a development process and a series of experiments, a surprisingly simple design was obtained for treating water with AC over DC that meets all the aforementioned functional requirements. For this purpose, classical power supply technology was combined with microcontroller technology on the one hand and the characteristic properties of the electrodes on the other hand. By subsequently switching the traditional power supply on and off with software, a robust and flexible electrical solution was obtained to apply the AC over DC technology in practice.

The electrical examples of the technology according to the present invention are further elucidated in the following examples. It is explicitly noted that the 8 examples are merely illustrative of the technology and in no way impose limitations on the present invention.

Example 1

For controlling the AC over DC application, use was made of the electronic circuit as shown in Figure 1.

Transformer TR1 is a 50 Hz transformer that is connected to the mains (230 V AC) with the primary coil. The secondary coil of TR1 has a center tap.

The transformer is dimensioned such that it can supply a secondary effective alternating voltage across the full winding of the 19 Volt secondary coil at a load on the 10 Ampere secondary coil. The secondary alternating voltage is rectified on both sides by means of diodes D1 and D2, both of which are of the BYV29 type. Coil L1 is a choke coil with an inductance of 100 milli Henry. Capacitor C1 is an electrolytic capacitor of 10,000 micro Farad.

The control block MC in figure 1 represents a circuit with a microcontroller of the PIC16F88 type. Block MC consists of microcontroller 16F88, a supply voltage for the 5.0 Volt microcontroller realized via a voltage regulator LM317, an external oscillator circuit with a 20 MHz crystal and 2 capacitors of 18 pF so that the microcontroller runs at a clock frequency of 20 MHz, ADC inputs for the microcontroller and digital outputs for the microcontroller. Transistor T1 of the BC547B type is connected to a digital output of the microcontroller via a resistor of 3.3k. This transistor is switched on and off with software. Resistance R1 is 235 Ohm, resistance R2 is 100 Ohm and resistance R3 is 470 Ohm.

Resistors R1 to R3 form a voltage divider and the values of R1 to R3 are chosen such that the voltage across R3 is less than 20 Volts. In Figure 1, T2 is drawn as if it were an NPN transistor. Although the circuit in Figure 1 functions well if T2 is an NPN power transistor, the use of an N FET such as the IRF640 is preferable to an NPN transistor. In Example 1, instead of T2, an N FET of the type IRF640 is used. Through software in the microcontroller, T1 and therefore T2 is alternately switched on and off. The FET T2 30 is operatively connected to the electrodes E2 and E1 of an electrolysis device. In the example, the electrolysis device consists of a 1000 ml beaker containing 2 metal plates, E1 and E2 respectively, both provided with a T102 coating and a NaCl solution of 25 grams of NaCl per liter. One of the electrodes E1 and E2 is connected to the FET and the other electrode to the plus of the power supply. The polarity of the electrodes can be reversed by switching relay i 35 RL1. The switching coil of relay RL1 is operatively connected via a switching transistor of the BC547B type to a digital output of the microcontroller. This makes it possible to software-reverse the polarity of electrodes E1 and E2 after an adjustable 9 period. This is important because in unpurified water there are calcium ions, carbonate ions, barium ions, sulfate ions and magnesium ions that can cause scaling on the electrodes during the electrolysis. By regularly reversing the polarity of the electrodes, scaling is prevented and, in most cases, even completely suppressed. For the experiment in Example 1, the microcontroller is provided with a software program that alternately turns on and off Transistor T1 and therefore also FET T2 with a frequency of 100 kHz. The consequence of this is that pulsed electrolysis occurs in the beaker via electrodes E1 and E2 by means of a square wave with a frequency of 100 kHz. During the experiment the voltage during the electrolysis was approximately 14 Volts (in the maximum of the block voltage). The time-average current was approximately 4 Ampere. The polarity of electrodes E1 and E2 was software reversed every 5 minutes and after a day no scaling appeared to be present on the electrodes. It was determined with an osdloscope that the voltage across E1 and E2 was a block voltage and that the polarity of this block voltage indeed reversed every 5 minutes.

Example 2

The experiment in example 1 has been repeated. However, in this case, a capacitor with a capacity of 1 micro Farad is placed parallel to electrodes E1 and E2. In this case, it was found that a time-average direct voltage of 6.65 Volts was present across the electrodes which fluctuated with a frequency of 100 kHz between 3.28 Volts and 9.2 Volts. The shape of the alternating DC voltage was changed from a block voltage to a "not perfect sine wave function". Example 2 clearly demonstrates that with the circuit in Figure 1 plus a capacitor between electrodes E1 and E2, an AC over DC can be realized according to the definition in this application. The time-average current during the experiment in Example 2 was approximately 5 Amps.

Example 3

The experiment in example 2 has been repeated. However, in this case, after capacitor C1 and in series with the plus of the power supply, a power resistance of 0.125 Ohm is included. A signal isolation transformer is connected in parallel to this power resistor. The ratio of the number of primary windings to the number of secondary windings was 1: 1. The signal transformer is suitable for transmitting frequencies up to 500 kHz. After the electrolysis was started, an alternating voltage on the secondary side of the transformer was measurable with a frequency of 100 kHz and an amplitude of approximately 1 Volt. This alternating voltage was then rectified on one side with a diode of the BYV29 type and an electrolytic capacitor of 1 micro Farad / 63V. The DC voltage thus obtained was supplied to an input of an ADC (analog to digital converter) of the microcontroller PIC16F88 which is present in block MC. Software was then translated the voltage measured by the ADC into a time-averaged current. If the current exceeded the desired value, the 100 kHz signal was alternated by software during a period in which FET T2 was out of conduction. A kind of duty cycle was set in this way in such a way that the time-averaged current through 5 electrodes E1 and E2 was approximately 5 Amps. The saline solution in the beaker was then replaced by a saline solution with a salinity of 100 grams per liter. The electrolysis unit according to Figure 1 was switched on and it was observed that the software automatically adjusted the duty cycle such that the time-average current through the electrodes was 4.9 Amps. After this, the saline in the beaker was replaced by a saline with a salinity of 10 grams of salt per liter. The result of this was that the voltage across electrodes E1 and E2 increased from approximately 8 volts as a maximum value to approximately 12 volts as a maximum value and that the time-average current remained approximately equal to 5 Amps. After a number of simulations of the electrical circuit in Figure 1 with the Edison simulation package, it was found that the ohmic resistance of diodes D1 and D2 together with the ohmic resistance of the secondary winding of TR1 and the ohmic resistance of L1 together with the self-inductance L of L1 ensure that the voltage across E1 and E2 collapses with increasing load. This phenomenon is conveniently used in Example 3 to keep the electrolysis current constant with changing salt concentration. In summary, example 3 clearly demonstrates that with the technology according to the present invention the time-average current can be adjusted by software by periodically switching off the FET by means of software if the time-average current exceeds the desired maximum value. Furthermore, example 3 clearly demonstrates that the characteristic properties of TR1, L1 and C1 ensure that with varying salt concentrations in the electrolysis unit, the voltage across E1 and E2 is adjusted via a self-regulating mechanism such that the current through the electrolysis unit is stabilized.

Example 4

A chlorine sensor is placed in the beaker in which the electrodes are located (the electrolysis reactor). The chlorine sensor generates a 4 mA to 20 mA signal that is related to the active chlorine content measured in the beaker. The resistor converts the 4 mA to 20 mA signal into a voltage. This voltage is supplied to the microcontroller via a second ADC input from the PIC microcontroller in unit MC. The signal is then read out using software. The software is configured such that chlorine production continues until the active chlorine content measured by the sensor equals 10 ppm. The electrolysis unit is then switched on and after a short period the electrolysis unit switches off with software. Changing the saline solution in the beaker causes the electrolysis unit 11 to start up again with software. This clearly demonstrates that the circuit in Figure 1 is suitable for automatically and software switching chlorine production on and off when the chlorine content in the liquid falls below or exceeds the desired value.

Example 5

The experiment in example 4 is repeated, but the circuit is increased with a data logger. The data logger stores the time-averaged current measured by software. This stream is a direct measure of the amount of active chlorine produced. After calibration, the total amount of active chlorine produced was found to correspond well with the amount of chlorine produced by means of the data logger and time-average flow.

Example 6

The experiments in Examples 1 to 5 were repeated. However, in this case an electrolytic capacitor of 10,000 micro Farad was connected directly behind diodes D1 and D2, i.e. the + of the electrolytic capacitor on the cathode of diodes D1 and D2 and the - of the electrolytic capacitor on the minus of the nutrition. A C-L-C filter was obtained in this way. It was clearly observed that the peak value of the voltage across electrodes E1 and E2 was now practically constant in a load range of 1 Ampere to 6 Ampere and that it was possible, depending on the salt concentration in the water, to achieve the desired time-average current intensity through the duty cyde configure.

Example 7

The experiments in Examples 1 to 6 were repeated. However, in this case, the electronic circuit was built in a Faraday cage, shielded cables were used to transport the electrical energy from the power supply to the electrolysis cell, and the electrolysis cell was also placed in a Faraday cage. EMC tests showed that the disinfection equipment meets the ICNIRP guidelines. Furthermore, no measurable malfunction of the electrolysis equipment appeared to enter the electricity grid. As a result, it was not necessary to provide the electrolysis device with a mains filter 30 on the primary side of the isolation transformer. It is noted that such a net filter can be placed if necessary or can be placed as extra safety. Such a filter forms part of the technology according to the present invention.

The examples show that, despite its simplicity, the designed electronic circuit has the following unique properties: • Good electromagnetic compatibility.

• Automatic control of the time-average current 12 • Automatic control of the chlorine content in the liquid • Automatic and periodic reversal of the polarity of the electrodes to prevent scaling.

• Great stability with varying salt concentrations in the water to be treated.

It is noted that the conventional power supply consisting of TR1, D1, D2, L1, C1 can also be replaced by a switching power supply. The electronic circuit according to Figure 1 as well as a configuration that is combined with a switching power supply is emphatically part of the present invention.

It is further noted that the circuit as set forth in Examples 1 to 6 is pre-eminently suitable for upscaling to high power i.e., to electrolysis currents up to 300 Amps. Extensive analysis of the circuit in combination with model simulations in the Edison software program for dynamic simulation of electronic circuits shows that the control for the FET as shown in Figure 1 is extremely suitable for controlling an IGBT. Such an IGBT (insulated gate bipolar transistor) can switch currents up to 300 Amps and can be effectively controlled with the microcontroller circuit as described in Examples 1 to 6. Furthermore, when high power is used, a current coil can be used. Such a coil consists of a coil body through which a current carrying wire is guided. As a result of the pulsed direct voltage an alternating voltage is created in the coil which, after rectification, can be supplied to an ADC input of the microcontroller.

In order to be able to use the technology according to the present invention without causing interference by electromagnetic waves, the electronic circuit must be built in a Faraday cage. Use should also be made of shielded cable that runs from the electronic circuit to the electrolysis cell. The electrolysis cell must also be built into a Faraday cage.

Finally, the frequency of the AC component of the AC alternating DC voltage is defined. The AC component has a frequency in the range between 0.01 Hz and 10 GHz. Preferably, the frequency of the AC component is in the range of 1 Hz and 100 MHz. More preferably, the frequency of the AC component is in the range of 1 kHz to 1 MHz. Even more preferably, the frequency of the AC component is in the range of 10 kHz to 500 kHz. Most preferably, the frequency of the AC component is in the range of 50 kHz to 250 kHz.

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.

1038115

Claims (32)

Device as claimed in claim 1, wherein the means for at least partially smoothing the direct current comprise at least one choke coil. Device according to one of the preceding claims 1 and 2 plus at least one smoothing capacitor. 4. Device as claimed in any of the foregoing claims 1-3, wherein the means for converting the direct current into an alternating direct current comprise at least one microprocessor and / or microcontroller. Device according to one of the preceding claims 1 to 4, wherein the electrolysis reactor itself forms a Faraday cage or is housed in a Faraday cage. Device according to one of the preceding claims 1 to 5, wherein the electrolysis reactor has a residence time for the liquid to be disinfected that is shorter than 1 minute. Device as claimed in any of the foregoing claims 1-6, wherein at least one of the electrodes is provided with a titanium oxide coating. Device according to one of the preceding claims 1 to 7, wherein at least one of the electrodes is used as a sacrificial electrode. The device of claim 8 wherein the sacrificial electrode contains at least carbon. 10. Device as claimed in any of the foregoing claims 7 to 9, wherein the sacrificial electrode comprises at least silver and / or silver ions and / or silver salts and / or silver oxide. II. Device as claimed in any of the foregoing claims 7 to 10, wherein the sacrificial electrode comprises at least copper and / or copper ions and / or copper salts and / or copper oxide. Device as claimed in any of the foregoing claims 1 to 11 plus a capacitor which is connected in parallel with the electrodes of the electrolysis reactor. An apparatus according to any one of the preceding claims 1 to 12 plus 1038115 a current sensor which feeds a reflection of the current through the electrolysis reactor at an ADC input of the microcontroller. 14. Device as claimed in claim 13 plus software to alternately switch the AC over DC electrolysis on and off by means of a duty cycle when the time-average electrolysis current exceeds a predefined value and software to adjust the duty cycle iteratively so that the desired time-average current passes through the electrodes of the electrolysis reactor are running. Device according to one of the preceding claims 1 to 14 for the disinfection of drinking water. Device according to one of the preceding claims 1 to 14 for the disinfection of sewage or waste water from hospitals. Device according to one of the preceding claims 1 to 14 for the disinfection of ballast water in ships. Device as claimed in any of the foregoing claims 1 to 14 for the disinfection of cooling water. Device according to one of the preceding claims 1 to 14 for the disinfection of foodstuffs such as fruit juices, milk products, beer, wine. 20. Device as claimed in any of the foregoing claims 1 to 14 for the disinfection of installations that come into contact with foodstuffs such as equipment in dairy factories, beer breweries, fruit juice factories. Device as claimed in any of the foregoing claims 1 to 20 plus a device for ultrasonic disinfection. Device according to one of the preceding claims 1 to 21 plus a device for disinfection with UVC radiation. Device as claimed in any of the foregoing claims 1 to 22 plus a device for disinfection with radio waves and / or high-frequency alternating voltage according to the definition in this application. Device as claimed in any of the foregoing claims 1 to 23 plus an ozone disinfection device. Device according to one of the preceding claims 1 to 20 plus a device for chlorine dioxide disinfection. The device according to any of the preceding claims 1 to 25, wherein the AC component of the alternating direct voltage AC across DC has a frequency in the range of 1 kHz to 1 MHz. Device according to one of the preceding claims 1 to 26, in which an IGBT is used to scale up the electrolysis reactor. The device of claim 27, wherein the time-average alternating direct current is more than 50 Amps. Device according to one of the preceding claims 1 to 28, wherein the electrical energy is transported from the power source to the electrolysis cell through a shielded electricity cable. Device according to one of the preceding claims 1 to 29, wherein the housing of the power source is a Faraday cage. Device as claimed in any of the foregoing claims 1 to 30 plus a mains filter to prevent malfunctions of the electrolysis device in the mains. 32. Device as claimed in any of the foregoing claims 1 to 31, wherein the supply source supplying a direct current is a switching supply. A method for disinfecting a liquid characterized by a device according to any of the preceding claims 1 to 32. 34. Method for the production of a device according to one of the preceding claims 1 to 32. 20 25 30 35 1038115