NL1036984C2 - METHOD AND APPARATUS FOR THE PRODUCTION OF OZONE AND / OR RADICALS AND / OR UV RADIATION. - Google Patents

Description

Method and device for the production of ozone and / or radicals and / or UV radiation

The present invention relates to a method and device for the production of ozone and / or radicals and / or UV radiation characterized by a microprocessor controlled function generator, an amplifier consisting of at least one transistor, a high voltage transformer and one or more electrodes in the form of a 2 wire or other mass-produced parallel conductors with an insulating coating.

10 Introduction

To cope with the growing worldwide shortage of drinking water, there is a great need for sustainable water purification technology that makes it possible to produce drinking water and clean waste water at low energy costs and without the use of chemicals.

The present invention relates to a water purification technology with the above characteristics. With the technology according to the present invention, it is possible to disinfect and / or purify water on a large scale (order size 1000 - 10,000 m3 water per hour) and on a small scale (order size 10 liters per hour). The technology according to the present invention uses little energy and does not use chemicals. Also, the investment in the equipment needed to treat the water according to the present invention is low. In addition, the equipment according to the present invention is robust, simple and compact and the energy supply of the equipment can take place via solar cells or a dynamo powered by manpower. In addition to the purification of water, the technology according to the present invention can also be used to purify and / or disinfect air, to produce synthesis gas from bio-waste, to safely produce radicals for carrying out chemical reactions such as chlorination of organic compounds and polymerization reactions including emulsion polymerization.

Technical description of the present invention

According to a first aspect, the technology consists of a function generator that generates a sine wave and / or a square wave and / or a sawtooth and / or a pulse with a very precisely adjustable frequency. According to a second aspect, the technology consists of a power supply which supplies a preferably smoothed DC voltage and which is connected via transistors 35 to the primary coil (s) of a high-voltage transformer in such a way that a current flows in the rhythm of the signal through the high-voltage transformer. with which the transistors are controlled by the function generator. The secondary coil of the high voltage transformer has such a number of turns with respect to the primary coil (s) that the impedance of the transformer on the secondary side is tuned to the impedance of an electrode forming a corona such that ozone and / or radicals are being produced.

According to a third aspect, the technology according to the present invention consists of an electrode which is connected to the secondary side of the transformer. This electrode may consist of a conventional electrode according to the state of the art or of a 2-core cable in which a corana is formed between the insulation material of the cable. A 2-core cable is particularly suitable for use in combination with the present invention 10 since it is inexpensive, can be mass-produced very reproducibly and has the same dielectric properties over the entire length. According to a fourth aspect, the present invention consists of a housing on which contacts are arranged on the outside. These contacts make it possible to connect several housings to each other by means of a click system and in this way provide all housings with power since the ozone generator in each housing is connected in parallel to the other housings by means of the click system. According to a fifth aspect, the present invention is characterized by a central power supply that supplies a safe low voltage, preferably 24 V, to which all the housings are connected via the contacts of the snap system.

Now that the principle of the technology according to the present invention is known, a non-limitative list of a number of embodiments follows:

In a first embodiment, use is made of a switching power supply which supplies a direct voltage or an alternating voltage in the range of 1 Volt to 100 Volts. Use is preferably made of a DC voltage of 24 Volt which is supplied by a preferably centrally arranged switching power supply. This power supply is connected to the contacts of ozone generator 1. The ozone generator 1 contains a second set of contacts that are also electrically connected to the DC voltage of 24 Volts. An ozone generator 2 can then be connected to ozone generator 1 by means of a click system, with the result that the contacts of ozone generator 1 are in electrical connection with those of ozone generator 2. The result is that ozone generator 2 is electrically connected to ozone generator 1 in this way and thus also with the 24 Volt power supply. By making a number of identical ozone generators, a system is obtained in this way that makes coupling of ozone generators to increase capacity very simple. Since the voltage transmitted from 35 ozone generator to ozone generator is a low voltage (in this case 24 Volts), the system is inherently safe and, if desired, a simple click system with exposed contacts can be used. An electrical circuit is present in each ozone generator which converts the direct voltage into a voltage that is adjusted to the electrical properties of the ozone-producing electrode. The electrical circuit preferably consists of a microprocessor which supplies a pulsed direct voltage on at least 1 but preferably on 2 channels and in reverse phase. If channel 5 1 is switched on, channel 2 is switched off and vice versa. The channels are switched on and off with the clock frequency of the microprocessor as the time base. In this way a very stable frequency of the function generator is obtained which hardly runs. The signal supplied by the microprocessor is then used to switch one or more transistors which then, with the frequency at which the microprocessor is programmed, pass a current through the primary coil of the high-voltage transformer. This creates a voltage in the secondary coil of the transformer and a current flows through the electrode that is connected to the secondary side of the high-voltage transformer.

In a second embodiment, one of the earlier embodiments is used in which in each housing which is supplied with electrical energy by the central supply, the current supplied to the ozone generator in the relevant housing is measured. This measurement takes place via an AD converter which is connected to the microprocessor which serves as a function generator for switching the ozone generator in the relevant housing. The AD converter is preferably integrated in the microprocessor. If the current through the electronic circuit in the relevant housing becomes too large, it can be decided that the microprocessor switches off and only switches on again if the power supply is interrupted. It is clear to the person skilled in the art that in this way we have realized a software fuse which uses the microprocessor that is already present in each housing to control the ozone generator. Furthermore, it is clear to those skilled in the art that the sensor to measure the current supplied to the electronic circuit in each housing may consist of a resistor in series with the electronic circuit for the ozone generator in each housing. However, use can also be made of a light sensor, a sensor for magnetic fields, a sensor for electric fields, a sensor for electromagnetic fields, a sensor for ultrasonic vibrations or an acoustic sensor. If desired, the signal supplied by one or more of these sensors can be used to automatically optimize the operation of each ozone generator via a feedback. This can be done by means of software in the microprocessor which automatically sets the function generator to the optimum frequency if it proceeds due to, for example, wear of the electrodes.

In a third embodiment, the central power supply used in embodiments 1 and 2 consists of a switching power supply constructed in a similar manner 4 as each individual power supply is designed for the ozone generator in each housing. Such a power supply thus preferably consists of a microprocessor that is programmed as a function generator, switching transistors and a transformer. In this case, the alternating voltage of the public electricity network is preferably rectified. Subsequently this direct current voltage is connected to at least 1 switching transistor, preferably a FET similar to the type IRF840. The switching transistor (s) are driven by the microprocessor that is used as a function generator and are connected to at least one primary coil of an isolating transformer. As a result, a current will flow through the primary coil in the rhythm of the signal generated by the microprocessor. The consequence of this is that an alternating voltage is generated across the secondary coil of the transformer. By now tuning the ratio of the number of turns of the primary and secondary coil to each other in accordance with known principles and then aligning them and possibly smoothing them, it can be ensured that the central supply supplies a DC voltage of 24V. The central power supply can also be protected against overloading by using a circuit as described in earlier embodiments.

In a fourth embodiment, in order to prevent the equipment according to the present invention from interfering with other devices, one of the embodiments 1 to 3 is combined with conventional filtering techniques to prevent the alternating voltage that is generated from interfering with other equipment by displacement via the mains or because the circuit according to the present invention behaves as a transmitter. It is noted here that the design of the required filter is simple and efficient since the alternating voltage is generated with a microprocessor as a function generator and, consequently, the frequency of alternating voltage generated by the function generator does not, or hardly, expires. This makes it possible to use a very selective filter with narrow bandwidth to prevent interference from the switching power supply on other systems.

Example 1

A battery of V1 which supplies a voltage of 24V was connected to the circuit in figure 1. The function of the components in figure 1 is now successively explained as well as the operation of the circuit. Capacitor C3 with a capacity of 1000 pF / 100V is a smoothing capacitor that absorbs the varying load of battery V1. Transistors T3 and T4 are of the BC547B type, are fed by a function generator via points A and B and serve to amplify the signal supplied by the function generator 35. Resistors R1 and R2 both with a value of 100 Ohm limit the current that flows through collector and emitter of transistors T3 and T4. Transistors T3 and T4 are of the IRF540 type. The function generator is connected to points A and B. The function generator alternately supplies a signal to point A and point B. In other words: First, point A is supplied by the function generator with a voltage equal to 5 volts. This voltage is then kept at 5 volts for a time t1 seconds. The function generator then makes the voltage at point A equal to 0 volts. As soon as the 5 voltage at point A is zero volts, the function generator switches the voltage at point B to 5 volts. This voltage is also kept at 5 volts for t1 seconds while the voltage at point A is still 0 volts. After the voltage at point B has been kept at 5 volts for t1 seconds, it is brought back to 0 volts and the voltage at point A is brought back to 5 volts. This cycle repeats itself endlessly. The consequence of this is that transistors T3 and T4 are switched on and off alternately. This then has the consequence that the FETT2 is switched alternately via C2 with a capacity of 4.7 pF and R6 with a value of 300 ohms, the FETT1 and via C1 with a capacity of 4.7 pF and R5 with a value of 300 ohms. The consequence of this is that the current through the primary coil of transformer TR1 flows through FET T1 and FET T2 via the center tip of TR1. This leads to transformer TR1 being provided in an extremely efficient manner with an alternating current which in this case is transformed upwards by TR1 to a desired value i e., To that value which is required for the load L1, the electrode, at the desired power. to make it work.

Now that the operation of the circuit in Fig. 1 is known, it is briefly explained how the desired signal can be realized with great accuracy and stability at points A and B in an efficient manner. This is done with a microprocessor. In this case, the microprocessor PIC16F84A has been used, but for the application according to the present invention a range of microprocessors can be used. This microprocessor was powered via battery V1. To this end, the voltage of 24V supplied by V1 was lowered by using a voltage regulator of the LM317 type. This voltage regulator was set according to the diagram in the accompanying data sheet to a constant voltage of 5 Volts. This output voltage of the LM317 was supplied to the microprocessor. Furthermore, the clock speed of the microprocessor was set using an external 20 MHz crystal, all this as indicated in the data sheet of the PIC16F84A. The microprocessor was programmed to make alternate outputs RB1 and RB2 "high" (ie to bring them to 5 volts). The output RB1 was connected to point A in Figure 1 and the output RB2 to point B. By applying the circuit just described, the desired frequency at which the switching power supply operates can be set by software. This allows the circuit to be used flexibly. The microprocessor PIC16F84A was programmed at a frequency of 6 kHz. The transformer TR1 used was a self-wound high-voltage transformer with center tip on the primary side, which transforms the voltage from the primary coil up to 6 to 15 kV. A piece of 2-wire 60-cm speaker cable was connected to the secondary coil, designated L1 in Figure 1. The circuit was turned on and it turned out that the ozone generator made a hissing noise, that a purple corona glow arose between the two conductors of the 2-core cable and that it smelled ozone 5 within a few seconds. Furthermore, the circuit turned out to be very efficient. The FETs T1 and T2 did not heat up at a power consumption of 20 watts.

It is clear to the skilled person that this circuit can still be considerably optimized. However, the example shows very clearly that the technology according to the present invention works and that ozone generators can be supplied with energy with a very high efficiency, the energy source being a low voltage which in this case is 24 Volts. It is noted that the circuit for the smart coupling of ozone generators with a click system as described in this application is only an example. The system as described in this application as well as the electronic control is generally applicable for ozone generator systems. Such ozone generator systems are emphatically part of the present invention.

20 25 30 35 1036984

Claims (27)

Device for the production of ozone or radicals or UV radiation characterized by • at least one power supply for supplying electrical power to a load operatively connected to S • a function generator and • means to control the frequency of the alternating voltage or the alternating direct voltage function generator provides accurate adjustment and keeping stable and • an amplifier to amplify the signal that the function generator supplies in voltage and / or current comprising at least one transistor or electron tube and • at least one high voltage transformer that is operatively connected to the amplifier and • at least two electrodes operatively connected to the output of the high voltage transformer Device as claimed in claim 1, wherein at least a part of the electrodes consists of 2 parallel conductors with an insulating coating between them 3. Device as claimed in any of the foregoing claims 1 and 2, wherein the electrodes consist of at least a 2-core cable, such as a commercially available speaker cable. A first device according to any of the preceding claims 1 to 4, wherein electrical contacts are arranged on the housing of this first device and at least a second device according to any of the preceding claims 1 to 4, wherein the housing of this second device also electrical contacts are provided wherein the first device and at least one second device are connected in parallel by operatively connecting the contacts on the housing and consequently the first device and at least one second device are powered from the same power supply. 5. Device as claimed in any of the foregoing claims 1-4, wherein the power supply supplies an alternating voltage or a direct voltage that is lower than 100 volts. Device as claimed in any of the foregoing claims 1-4, wherein the rotting source supplies an alternating voltage or a direct voltage that is lower than or equal to 24 volts. Device according to one of the preceding claims 1 to 4, wherein the power supply supplies a direct voltage or an alternating voltage that is lower than or equal to 12 volts. 1036984 Device according to one of the preceding claims 1 to 4, wherein the power supply supplies a direct voltage or an alternating voltage that is lower than or equal to 6 volts. 9. Device as claimed in any of the foregoing claims 1-8, wherein the power supply source supplying a direct voltage or an alternating voltage comprises at least a battery or a battery or a solar cell or a dynamo driven by manpower. 10. Device as claimed in any of the foregoing claims 1-9, wherein the function generator and the means for accurately adjusting the frequency of the alternating voltage or the alternating direct voltage which the function generator supplies are integrated in a microprocessor according to the definition in this application , for example, a microcontroller of the type PIC16F84A. 11. Device as claimed in any of the foregoing claims 1-10, plus a sensor which measures the power absorbed by the device directly or indirectly and which switches off the device as soon as the power exceeds a set value. Device according to any of the preceding claims 1 to 11, wherein the sensor is a resistor in series with the power supply. Device as claimed in any of the foregoing claims 1 to 11, wherein the sensor 20 is a light sensor. Device according to one of the preceding claims 1 to 11, wherein the sensor is an ultrasonic sensor or an acoustic sensor. Device according to one of the preceding claims 1 to 11, wherein the sensor is a magnetic field sensor. Device according to one of the preceding claims 1 to 11, wherein the sensor is an electric field sensor. Device according to any of the preceding claims 1 to 11, wherein the sensor is an electromagnetic field sensor. 18. Device as claimed in any of the foregoing claims 1 to 17, wherein with the aid of the signal measured by the sensor by means of software in a microprocessor the frequency of the function generator is set to the optimum value as soon as this optimum frequency deviates from the set value due to wear of the electrodes. 19. Device as claimed in any of the foregoing claims 1 to 18, wherein the power supply is a switching power supply. Device according to one of the preceding claims 1 to 19, wherein the frequency of the function generator is stabilized by the use of a crystal. 1 036984 Device as claimed in any of the foregoing claims 1 to 20 plus a filter with a very narrow bandwidth to prevent interference via the power supply or through antenna action on other systems in the environment. 22. Device as claimed in any of the foregoing claims 1-21, wherein the high-voltage transformer is of the push-pull transformer type with at least a center tip on the primary side. Method for the production of ozone or radicals with a device according to one of the preceding claims 1 to 22, characterized by the use of a function generator 10. means for accurately measuring the frequency of the alternating voltage or the alternating direct voltage that the function generator supplies to be adjusted and kept stable • an amplifier to amplify the signal that the function generator supplies in voltage and / or current comprising at least one transistor or electron tube • at least one high voltage transformer 24. Method for purification of water including disinfection of water with a device according to any of the preceding claims 1 to 22, characterized by bringing water into contact with ozone or water with radicals which, by means of the device according to claims 1 to m 22 have been produced. A method for the purification of air with an apparatus according to any one of the preceding claims 1 to 22, characterized by bringing air into contact with ozone or air with radicals which are controlled by means of the apparatus according to claims 1 to 22 produced. Method for carrying out chemical reactions such as chlorination of organic compounds and polymerization reactions including emulsion polymerization with a device according to one of the preceding claims 1 to 22, characterized by contacting organic compounds including monomers with ozone or with radicals produced by the device according to claims 30. to 22. A process for the production of synthesis gas from bio-waste with a device according to claims 1 to 22, characterized by bringing bio-waste into contact with ozone or with radicals which have been treated by means of the device according to claims 1 to 22 produced. 1036984 35